def linear_calculate_chunks(chunks, features, approximate, training_window, profile, verbose, save_progress, entityset, no_unapproximated_aggs, cutoff_df_time_var, target_time, pass_columns): backend = PandasBackend(entityset, features) feature_matrix = [] # if verbose, create progess bar if verbose: pbar_string = ("Elapsed: {elapsed} | Remaining: {remaining} | " "Progress: {l_bar}{bar}| " "Calculated: {n}/{total} chunks") chunks = make_tqdm_iterator(iterable=chunks, total=len(chunks), bar_format=pbar_string) for chunk in chunks: _feature_matrix = calculate_chunk(chunk, features, approximate, training_window, profile, verbose, save_progress, no_unapproximated_aggs, cutoff_df_time_var, target_time, pass_columns, backend=backend) feature_matrix.append(_feature_matrix) # Do a manual garbage collection in case objects from calculate_chunk # weren't collected automatically gc.collect() if verbose: chunks.close() return feature_matrix
def linear_calculate_chunks(chunks, feature_set, approximate, training_window, verbose, save_progress, entityset, no_unapproximated_aggs, cutoff_df_time_var, target_time, pass_columns): feature_matrix = [] # if verbose, create progess bar if verbose: pbar_string = ("Elapsed: {elapsed} | Remaining: {remaining} | " "Progress: {l_bar}{bar}| " "Calculated: {n}/{total} chunks") chunks = make_tqdm_iterator(iterable=chunks, total=len(chunks), bar_format=pbar_string) for chunk in chunks: _feature_matrix = calculate_chunk(chunk, feature_set, entityset, approximate, training_window, verbose, save_progress, no_unapproximated_aggs, cutoff_df_time_var, target_time, pass_columns) feature_matrix.append(_feature_matrix) # Do a manual garbage collection in case objects from calculate_chunk # weren't collected automatically gc.collect() if verbose: chunks.close() return feature_matrix
def encode_features(feature_matrix, features, top_n=10, include_unknown=True, to_encode=None, inplace=False, verbose=False): """Encode categorical features Args: feature_matrix (pd.DataFrame): Dataframe of features features (list[:class:`.PrimitiveBase`]): Feature definitions in feature_matrix top_n (pd.DataFrame): number of top values to include include_unknown (pd.DataFrame): add feature encoding an unkwown class. defaults to True to_encode (list[str]): list of feature names to encode. features not in this list are unencoded in the output matrix defaults to encode all necessary features inplace (bool): encode feature_matrix in place. Defaults to False. verbose (str): Print progress info. Returns: (pd.Dataframe, list) : encoded feature_matrix, encoded features Example: .. ipython:: python :suppress: from featuretools.tests.testing_utils import make_ecommerce_entityset from featuretools.primitives import Feature import featuretools as ft es = make_ecommerce_entityset() .. ipython:: python f1 = Feature(es["log"]["product_id"]) f2 = Feature(es["log"]["purchased"]) f3 = Feature(es["log"]["value"]) features = [f1, f2, f3] ids = [0, 1, 2, 3, 4, 5] feature_matrix = ft.calculate_feature_matrix(features, instance_ids=ids) fm_encoded, f_encoded = ft.encode_features(feature_matrix, features) f_encoded fm_encoded, f_encoded = ft.encode_features(feature_matrix, features, top_n=2) f_encoded fm_encoded, f_encoded = ft.encode_features(feature_matrix, features, include_unknown=False) f_encoded fm_encoded, f_encoded = ft.encode_features(feature_matrix, features, to_encode=['purchased']) f_encoded """ if inplace: X = feature_matrix else: X = feature_matrix.copy() encoded = [] if verbose: iterator = make_tqdm_iterator(iterable=features, total=len(features), desc="Encoding pass 1", unit="feature") else: iterator = features for f in iterator: if (f.expanding or (not issubclass(f.variable_type, Discrete))): encoded.append(f) continue if to_encode is not None and f.get_name() not in to_encode: encoded.append(f) continue unique = X[f.get_name()].value_counts().head(top_n).index.tolist() for label in unique: add = f == label encoded.append(add) X[add.get_name()] = (X[f.get_name()] == label).astype(int) if include_unknown: unknown = f.isin(unique).NOT().rename(f.get_name() + " = unknown") encoded.append(unknown) X[unknown.get_name()] = (~X[f.get_name()].isin(unique)).astype(int) X.drop(f.get_name(), axis=1, inplace=True) new_X = X[[e.get_name() for e in encoded]] iterator = new_X.columns if verbose: iterator = make_tqdm_iterator(iterable=new_X.columns, total=len(new_X.columns), desc="Encoding pass 2", unit="feature") for c in iterator: try: new_X[c] = pd.to_numeric(new_X[c], errors='raise') except (TypeError, ValueError): pass return new_X, encoded
def parallel_calculate_chunks(chunks, features, approximate, training_window, verbose, save_progress, entityset, n_jobs, no_unapproximated_aggs, cutoff_df_time_var, target_time, pass_columns, dask_kwargs=None): from distributed import Client, LocalCluster, as_completed from dask.base import tokenize client = None cluster = None try: if 'cluster' in dask_kwargs: cluster = dask_kwargs['cluster'] else: diagnostics_port = None if 'diagnostics_port' in dask_kwargs: diagnostics_port = dask_kwargs['diagnostics_port'] del dask_kwargs['diagnostics_port'] workers = n_jobs_to_workers(n_jobs) workers = min(workers, len(chunks)) cluster = LocalCluster(n_workers=workers, threads_per_worker=1, diagnostics_port=diagnostics_port, **dask_kwargs) # if cluster has bokeh port, notify user if unxepected port number if diagnostics_port is not None: if hasattr(cluster, 'scheduler') and cluster.scheduler: info = cluster.scheduler.identity() if 'bokeh' in info['services']: msg = "Dashboard started on port {}" print(msg.format(info['services']['bokeh'])) client = Client(cluster) # scatter the entityset # denote future with leading underscore start = time.time() es_token = "EntitySet-{}".format(tokenize(entityset)) if es_token in client.list_datasets(): print("Using EntitySet persisted on the cluster as dataset %s" % (es_token)) _es = client.get_dataset(es_token) else: _es = client.scatter([entityset])[0] client.publish_dataset(**{_es.key: _es}) # save features to a tempfile and scatter it pickled_feats = cloudpickle.dumps(features) _saved_features = client.scatter(pickled_feats) client.replicate([_es, _saved_features]) end = time.time() scatter_time = end - start scatter_string = "EntitySet scattered to workers in {:.3f} seconds" print(scatter_string.format(scatter_time)) # map chunks # TODO: consider handling task submission dask kwargs _chunks = client.map(calculate_chunk, chunks, features=_saved_features, entityset=_es, approximate=approximate, training_window=training_window, profile=False, verbose=False, save_progress=save_progress, no_unapproximated_aggs=no_unapproximated_aggs, cutoff_df_time_var=cutoff_df_time_var, target_time=target_time, pass_columns=pass_columns) feature_matrix = [] iterator = as_completed(_chunks).batches() if verbose: pbar_str = ("Elapsed: {elapsed} | Remaining: {remaining} | " "Progress: {l_bar}{bar}| " "Calculated: {n}/{total} chunks") pbar = make_tqdm_iterator(total=len(_chunks), bar_format=pbar_str) for batch in iterator: results = client.gather(batch) for result in results: feature_matrix.append(result) if verbose: pbar.update() if verbose: pbar.close() except Exception: raise finally: if 'cluster' not in dask_kwargs and cluster is not None: cluster.close() if client is not None: client.close() return feature_matrix
def calculate_all_features(self, instance_ids, time_last, training_window=None, profile=False, precalculated_features=None, ignored=None, verbose=False): """ Given a list of instance ids and features with a shared time window, generate and return a mapping of instance -> feature values. Args: instance_ids (list): List of instance id for which to build features. time_last (pd.Timestamp): Last allowed time. Data from exactly this time not allowed. training_window (Timedelta, optional): Data older than time_last by more than this will be ignored. profile (bool): Enable profiler if True. verbose (bool): Print output progress if True. Returns: pd.DataFrame : Pandas DataFrame of calculated feature values. Indexed by instance_ids. Columns in same order as features passed in. """ assert len(instance_ids) > 0, "0 instance ids provided" self.instance_ids = instance_ids self.time_last = time_last if self.time_last is None: self.time_last = datetime.now() # For debugging if profile: pr = cProfile.Profile() pr.enable() if precalculated_features is None: precalculated_features = {} # Access the index to get the filtered data we need target_entity = self.entityset[self.target_eid] if ignored: # TODO: Just want to remove entities if don't have any (sub)features defined # on them anymore, rather than recreating ordered_entities = FeatureTree(self.entityset, self.features, ignored=ignored).ordered_entities else: ordered_entities = self.feature_tree.ordered_entities necessary_columns = self.feature_tree.necessary_columns eframes_by_filter = \ self.entityset.get_pandas_data_slice(filter_entity_ids=ordered_entities, index_eid=self.target_eid, instances=instance_ids, entity_columns=necessary_columns, time_last=time_last, training_window=training_window, verbose=verbose) large_eframes_by_filter = None if any([ f.primitive.uses_full_entity for f in self.feature_tree.all_features if isinstance(f, TransformFeature) ]): large_necessary_columns = self.feature_tree.necessary_columns_for_all_values_features large_eframes_by_filter = \ self.entityset.get_pandas_data_slice(filter_entity_ids=ordered_entities, index_eid=self.target_eid, instances=None, entity_columns=large_necessary_columns, time_last=time_last, training_window=training_window, verbose=verbose) # Handle an empty time slice by returning a dataframe with defaults if eframes_by_filter is None: return self.generate_default_df(instance_ids=instance_ids) finished_entity_ids = [] # Populate entity_frames with precalculated features if len(precalculated_features) > 0: for entity_id, precalc_feature_values in precalculated_features.items( ): if entity_id in eframes_by_filter: frame = eframes_by_filter[entity_id][entity_id] eframes_by_filter[entity_id][entity_id] = pd.merge( frame, precalc_feature_values, left_index=True, right_index=True) else: # Only features we're taking from this entity # are precomputed # Make sure the id variable is a column as well as an index entity_id_var = self.entityset[entity_id].index precalc_feature_values[ entity_id_var] = precalc_feature_values.index.values eframes_by_filter[entity_id] = { entity_id: precalc_feature_values } finished_entity_ids.append(entity_id) # Iterate over the top-level entities (filter entities) in sorted order # and calculate all relevant features under each one. if verbose: total_groups_to_compute = sum( len(group) for group in self.feature_tree.ordered_feature_groups.values()) pbar = make_tqdm_iterator(total=total_groups_to_compute, desc="Computing features", unit="feature group") if verbose: pbar.update(0) for filter_eid in ordered_entities: entity_frames = eframes_by_filter[filter_eid] large_entity_frames = None if large_eframes_by_filter is not None: large_entity_frames = large_eframes_by_filter[filter_eid] # update the current set of entity frames with the computed features # from previously finished entities for eid in finished_entity_ids: # only include this frame if it's not from a descendent entity: # descendent entity frames will have to be re-calculated. # TODO: this check might not be necessary, depending on our # constraints if not self.entityset.find_backward_path( start_entity_id=filter_eid, goal_entity_id=eid): entity_frames[eid] = eframes_by_filter[eid][eid] # TODO: look this over again # precalculated features will only be placed in entity_frames, # and it's possible that that they are the only features computed # for an entity. In this case, the entity won't be present in # large_eframes_by_filter. The relevant lines that this case passes # through are 136-143 if (large_eframes_by_filter is not None and eid in large_eframes_by_filter and eid in large_eframes_by_filter[eid]): large_entity_frames[eid] = large_eframes_by_filter[ eid][eid] if filter_eid in self.feature_tree.ordered_feature_groups: for group in self.feature_tree.ordered_feature_groups[ filter_eid]: if verbose: pbar.set_postfix({'running': 0}) test_feature = group[0] entity_id = test_feature.entity.id input_frames_type = self.feature_tree.input_frames_type( test_feature) input_frames = large_entity_frames if input_frames_type == "subset_entity_frames": input_frames = entity_frames handler = self._feature_type_handler(test_feature) result_frame = handler(group, input_frames) output_frames_type = self.feature_tree.output_frames_type( test_feature) if output_frames_type in [ 'full_and_subset_entity_frames', 'subset_entity_frames' ]: index = entity_frames[entity_id].index # If result_frame came from a uses_full_entity feature, # and the input was large_entity_frames, # then it's possible it doesn't contain some of the features # in the output entity_frames # We thus need to concatenate the existing frame with the result frame, # making sure not to duplicate any columns _result_frame = result_frame.reindex(index) cols_to_keep = [ c for c in _result_frame.columns if c not in entity_frames[entity_id].columns ] entity_frames[entity_id] = pd.concat([ entity_frames[entity_id], _result_frame[cols_to_keep] ], axis=1) if output_frames_type in [ 'full_and_subset_entity_frames', 'full_entity_frames' ]: index = large_entity_frames[entity_id].index _result_frame = result_frame.reindex(index) cols_to_keep = [ c for c in _result_frame.columns if c not in large_entity_frames[entity_id].columns ] large_entity_frames[entity_id] = pd.concat([ large_entity_frames[entity_id], _result_frame[cols_to_keep] ], axis=1) if verbose: pbar.update(1) finished_entity_ids.append(filter_eid) if verbose: pbar.set_postfix({'running': 0}) pbar.refresh() sys.stdout.flush() pbar.close() # debugging if profile: pr.disable() ROOT_DIR = os.path.expanduser("~") prof_folder_path = os.path.join(ROOT_DIR, 'prof') if not os.path.exists(prof_folder_path): os.mkdir(prof_folder_path) with open( os.path.join(prof_folder_path, 'inst-%s.log' % list(instance_ids)[0]), 'w') as f: pstats.Stats(pr, stream=f).strip_dirs().sort_stats( "cumulative", "tottime").print_stats() df = eframes_by_filter[self.target_eid][self.target_eid] # fill in empty rows with default values missing_ids = [ i for i in instance_ids if i not in df[target_entity.index] ] if missing_ids: default_df = self.generate_default_df(instance_ids=missing_ids, extra_columns=df.columns) df = df.append(default_df, sort=True) df.index.name = self.entityset[self.target_eid].index column_list = [] for feat in self.features: column_list.extend(feat.get_feature_names()) return df[column_list]
def calculate_feature_matrix(features, cutoff_time=None, instance_ids=None, entities=None, relationships=None, entityset=None, cutoff_time_in_index=False, training_window=None, approximate=None, save_progress=None, verbose=False, backend_verbose=False, verbose_desc='calculate_feature_matrix', profile=False): """Calculates a matrix for a given set of instance ids and calculation times. Args: features (list[PrimitiveBase]): Feature definitions to be calculated. cutoff_time (pd.DataFrame or Datetime): Specifies at which time to calculate the features for each instance. Can either be a DataFrame with 'instance_id' and 'time' columns, DataFrame with the name of the index variable in the target entity and a time column, a list of values, or a single value to calculate for all instances. If the dataframe has more than two columns, any additional columns will be added to the resulting feature matrix. instance_ids (list): List of instances to calculate features on. Only used if cutoff_time is a single datetime. entities (dict[str -> tuple(pd.DataFrame, str, str)]): dictionary of entities. Entries take the format {entity id: (dataframe, id column, (time_column))}. relationships (list[(str, str, str, str)]): list of relationships between entities. List items are a tuple with the format (parent entity id, parent variable, child entity id, child variable). entityset (EntitySet): An already initialized entityset. Required if entities and relationships are not defined. cutoff_time_in_index (bool): If True, return a DataFrame with a MultiIndex where the second index is the cutoff time (first is instance id). DataFrame will be sorted by (time, instance_id). training_window (dict[str -> Timedelta] or Timedelta, optional): Window or windows defining how much older than the cutoff time data can be to be included when calculating the feature. To specify which entities to apply windows to, use a dictionary mapping entity id -> Timedelta. If None, all older data is used. approximate (Timedelta or str): Frequency to group instances with similar cutoff times by for features with costly calculations. For example, if bucket is 24 hours, all instances with cutoff times on the same day will use the same calculation for expensive features. verbose (bool, optional): Print progress info. The time granularity is per time group unless there is only a single cutoff time, in which case backend_verbose is turned on backend_verbose (bool, optional): Print progress info of each feature calculatation step per time group. profile (bool, optional): Enables profiling if True. save_progress (str, optional): path to save intermediate computational results. """ assert (isinstance(features, list) and features != [] and all([isinstance(feature, PrimitiveBase) for feature in features])), \ "features must be a non-empty list of features" # handle loading entityset from featuretools.entityset.entityset import EntitySet if not isinstance(entityset, EntitySet): if entities is not None and relationships is not None: entityset = EntitySet("entityset", entities, relationships) if entityset is not None: for f in features: f.entityset = entityset entityset = features[0].entityset target_entity = features[0].entity pass_columns = [] if not isinstance(cutoff_time, pd.DataFrame): if cutoff_time is None: cutoff_time = datetime.now() if instance_ids is None: index_var = target_entity.index instance_ids = target_entity.df[index_var].tolist() if not isinstance(cutoff_time, list): cutoff_time = [cutoff_time] * len(instance_ids) map_args = [(id, time) for id, time in zip(instance_ids, cutoff_time)] df_args = pd.DataFrame(map_args, columns=['instance_id', 'time']) to_calc = df_args.values cutoff_time = pd.DataFrame(to_calc, columns=['instance_id', 'time']) else: cutoff_time = cutoff_time.copy() # handle how columns are names in cutoff_time if "instance_id" not in cutoff_time.columns: if target_entity.index not in cutoff_time.columns: raise AttributeError( 'Name of the index variable in the target entity' ' or "instance_id" must be present in cutoff_time') # rename to instance_id cutoff_time.rename(columns={target_entity.index: "instance_id"}, inplace=True) if "time" not in cutoff_time.columns: # take the first column that isn't instance_id and assume it is time not_instance_id = [ c for c in cutoff_time.columns if c != "instance_id" ] cutoff_time.rename(columns={not_instance_id[0]: "time"}, inplace=True) pass_columns = [column_name for column_name in cutoff_time.columns[2:]] # Get dictionary of features to approximate if approximate is not None: to_approximate, all_approx_feature_set = gather_approximate_features( features) else: to_approximate = defaultdict(list) all_approx_feature_set = None # Check if there are any non-approximated aggregation features no_unapproximated_aggs = True for feature in features: if isinstance(feature, AggregationPrimitive): # do not need to check if feature is in to_approximate since # only base features of direct features can be in to_approximate no_unapproximated_aggs = False break deps = feature.get_deep_dependencies(all_approx_feature_set) for dependency in deps: if (isinstance(dependency, AggregationPrimitive) and dependency not in to_approximate[dependency.entity.id]): no_unapproximated_aggs = False break cutoff_df_time_var = 'time' target_time = '_original_time' if approximate is not None: # If there are approximated aggs, bin times binned_cutoff_time = bin_cutoff_times(cutoff_time.copy(), approximate) # Think about collisions: what if original time is a feature binned_cutoff_time[target_time] = cutoff_time[cutoff_df_time_var] grouped = binned_cutoff_time.groupby(cutoff_df_time_var, sort=True) else: grouped = cutoff_time.groupby(cutoff_df_time_var, sort=True) # if the backend is going to be verbose, don't make cutoff times verbose if verbose and not backend_verbose: iterator = make_tqdm_iterator(iterable=grouped, total=len(grouped), desc="Progress", unit="cutoff time") else: iterator = grouped feature_matrix = [] backend = PandasBackend(entityset, features) for _, group in iterator: _feature_matrix = calculate_batch( features, group, approximate, entityset, backend_verbose, training_window, profile, verbose, save_progress, backend, no_unapproximated_aggs, cutoff_df_time_var, target_time, pass_columns) feature_matrix.append(_feature_matrix) # Do a manual garbage collection in case objects from calculate_batch # weren't collected automatically gc.collect() feature_matrix = pd.concat(feature_matrix) if not cutoff_time_in_index: feature_matrix.reset_index(level='time', drop=True, inplace=True) if save_progress and os.path.exists(os.path.join(save_progress, 'temp')): shutil.rmtree(os.path.join(save_progress, 'temp')) return feature_matrix
def encode_features(feature_matrix, features, top_n=DEFAULT_TOP_N, include_unknown=True, to_encode=None, inplace=False, drop_first=False, verbose=False): """Encode categorical features Args: feature_matrix (pd.DataFrame): Dataframe of features. features (list[PrimitiveBase]): Feature definitions in feature_matrix. top_n (int or dict[string -> int]): Number of top values to include. If dict[string -> int] is used, key is feature name and value is the number of top values to include for that feature. If a feature's name is not in dictionary, a default value of 10 is used. include_unknown (pd.DataFrame): Add feature encoding an unknown class. defaults to True to_encode (list[str]): List of feature names to encode. features not in this list are unencoded in the output matrix defaults to encode all necessary features. inplace (bool): Encode feature_matrix in place. Defaults to False. drop_first (bool): Whether to get k-1 dummies out of k categorical levels by removing the first level. defaults to False verbose (str): Print progress info. Returns: (pd.Dataframe, list) : encoded feature_matrix, encoded features Example: .. ipython:: python :suppress: from featuretools.tests.testing_utils import make_ecommerce_entityset import featuretools as ft es = make_ecommerce_entityset() .. ipython:: python f1 = ft.Feature(es["log"]["product_id"]) f2 = ft.Feature(es["log"]["purchased"]) f3 = ft.Feature(es["log"]["value"]) features = [f1, f2, f3] ids = [0, 1, 2, 3, 4, 5] feature_matrix = ft.calculate_feature_matrix(features, es, instance_ids=ids) fm_encoded, f_encoded = ft.encode_features(feature_matrix, features) f_encoded fm_encoded, f_encoded = ft.encode_features(feature_matrix, features, top_n=2) f_encoded fm_encoded, f_encoded = ft.encode_features(feature_matrix, features, include_unknown=False) f_encoded fm_encoded, f_encoded = ft.encode_features(feature_matrix, features, to_encode=['purchased']) f_encoded fm_encoded, f_encoded = ft.encode_features(feature_matrix, features, drop_first=True) f_encoded """ if not isinstance(feature_matrix, pd.DataFrame): msg = "feature_matrix must be a Pandas DataFrame" raise TypeError(msg) if inplace: X = feature_matrix else: X = feature_matrix.copy() old_feature_names = set() for feature in features: for fname in feature.get_feature_names(): assert fname in X.columns, ( "Feature %s not found in feature matrix" % (fname)) old_feature_names.add(fname) pass_through = [col for col in X.columns if col not in old_feature_names] if verbose: iterator = make_tqdm_iterator(iterable=features, total=len(features), desc="Encoding pass 1", unit="feature") else: iterator = features new_feature_list = [] new_columns = [] encoded_columns = set() for f in iterator: # TODO: features with multiple columns are not encoded by this method, # which can cause an "encoded" matrix with non-numeric vlaues is_discrete = issubclass(f.variable_type, Discrete) if (f.number_output_features > 1 or not is_discrete): if f.number_output_features > 1: logger.warning("Feature %s has multiple columns and will not " "be encoded. This may result in a matrix with" " non-numeric values." % (f)) new_feature_list.append(f) new_columns.extend(f.get_feature_names()) continue if to_encode is not None and f.get_name() not in to_encode: new_feature_list.append(f) new_columns.extend(f.get_feature_names()) continue val_counts = X[f.get_name()].value_counts().to_frame() index_name = val_counts.index.name if index_name is None: if 'index' in val_counts.columns: index_name = 'level_0' else: index_name = 'index' val_counts.reset_index(inplace=True) val_counts = val_counts.sort_values([f.get_name(), index_name], ascending=False) val_counts.set_index(index_name, inplace=True) select_n = top_n if isinstance(top_n, dict): select_n = top_n.get(f.get_name(), DEFAULT_TOP_N) if drop_first: select_n = min(len(val_counts), top_n) select_n = max(select_n - 1, 1) unique = val_counts.head(select_n).index.tolist() for label in unique: add = f == label add_name = add.get_name() new_feature_list.append(add) new_columns.append(add_name) encoded_columns.add(add_name) X[add_name] = (X[f.get_name()] == label) if include_unknown: unknown = f.isin(unique).NOT().rename(f.get_name() + " is unknown") unknown_name = unknown.get_name() new_feature_list.append(unknown) new_columns.append(unknown_name) encoded_columns.add(unknown_name) X[unknown_name] = (~X[f.get_name()].isin(unique)) X.drop(f.get_name(), axis=1, inplace=True) new_columns.extend(pass_through) new_X = X[new_columns] iterator = new_X.columns if verbose: iterator = make_tqdm_iterator(iterable=new_X.columns, total=len(new_X.columns), desc="Encoding pass 2", unit="feature") for c in iterator: if c in encoded_columns: try: new_X[c] = pd.to_numeric(new_X[c], errors='raise') except (TypeError, ValueError): pass return new_X, new_feature_list
def calculate_all_features(self, instance_ids, time_last, training_window=None, profile=False, precalculated_features=None, ignored=None, verbose=False): """ Given a list of instance ids and features with a shared time window, generate and return a mapping of instance -> feature values. Args: instance_ids (list): list of instance id to build features for time_last (pd.Timestamp): last allowed time. Data from exactly this time not allowed training_window (:class:Timedelta, optional): Data older than time_last by more than this will be ignored profile (boolean): enable profiler if True verbose (boolean): print output progress if True Returns: pd.DataFrame : Pandas DataFrame of calculated feature values. Indexed by instance_ids. Columns in same order as features passed in. """ assert len(instance_ids) > 0, "0 instance ids provided" self.instance_ids = instance_ids self.time_last = time_last if self.time_last is None: self.time_last = datetime.now() # For debugging if profile: pr = cProfile.Profile() pr.enable() if precalculated_features is None: precalculated_features = {} # Access the index to get the filtered data we need target_entity = self.entityset[self.target_eid] if ignored: # TODO: Just want to remove entities if don't have any (sub)features defined # on them anymore, rather than recreating ordered_entities = FeatureTree(self.entityset, self.features, ignored=ignored).ordered_entities else: ordered_entities = self.feature_tree.ordered_entities eframes_by_filter = \ self.entityset.get_pandas_data_slice(filter_entity_ids=ordered_entities, index_eid=self.target_eid, instances=instance_ids, time_last=time_last, training_window=training_window, verbose=verbose) # Handle an empty time slice by returning a dataframe with defaults if eframes_by_filter is None: return self.generate_default_df(instance_ids=instance_ids) finished_entity_ids = [] # Populate entity_frames with precalculated features if len(precalculated_features) > 0: for entity_id, precalc_feature_values in precalculated_features.items( ): if entity_id in eframes_by_filter: frame = eframes_by_filter[entity_id][entity_id] eframes_by_filter[entity_id][entity_id] = pd.merge( frame, precalc_feature_values, left_index=True, right_index=True) else: # Only features we're taking from this entity # are precomputed # Make sure the id variable is a column as well as an index entity_id_var = self.entityset[entity_id].index precalc_feature_values[ entity_id_var] = precalc_feature_values.index.values eframes_by_filter[entity_id] = { entity_id: precalc_feature_values } finished_entity_ids.append(entity_id) # Iterate over the top-level entities (filter entities) in sorted order # and calculate all relevant features under each one. if verbose: total_groups_to_compute = sum( len(group) for group in self.feature_tree.ordered_feature_groups.values()) pbar = make_tqdm_iterator(total=total_groups_to_compute, desc="Computing features", unit="feature group") if verbose: pbar.update(0) for filter_eid in ordered_entities: entity_frames = eframes_by_filter[filter_eid] # update the current set of entity frames with the computed features # from previously finished entities for eid in finished_entity_ids: # only include this frame if it's not from a descendent entity: # descendent entity frames will have to be re-calculated. # TODO: this check might not be necessary, depending on our # constraints if not self.entityset.find_backward_path( start_entity_id=filter_eid, goal_entity_id=eid): entity_frames[eid] = eframes_by_filter[eid][eid] if filter_eid in self.feature_tree.ordered_feature_groups: for group in self.feature_tree.ordered_feature_groups[ filter_eid]: if verbose: pbar.set_postfix({'running': 0}) handler = self._feature_type_handler(group[0]) handler(group, entity_frames) if verbose: pbar.update(1) finished_entity_ids.append(filter_eid) if verbose: pbar.set_postfix({'running': 0}) pbar.refresh() sys.stdout.flush() pbar.close() # debugging if profile: pr.disable() s = cStringIO.StringIO() ps = pstats.Stats(pr, stream=s).sort_stats("cumulative", "tottime") ps.print_stats() prof_folder_path = os.path.join(ROOT_DIR, 'prof') if not os.path.exists(prof_folder_path): os.mkdir(prof_folder_path) with open( os.path.join(prof_folder_path, 'inst-%s.log' % list(instance_ids)[0]), 'w') as f: f.write(s.getvalue()) df = eframes_by_filter[self.target_eid][self.target_eid] # fill in empty rows with default values missing_ids = [ i for i in instance_ids if i not in df[target_entity.index] ] if missing_ids: df = df.append( self.generate_default_df(instance_ids=missing_ids, extra_columns=df.columns)) return df[[feat.get_name() for feat in self.features]]
def parallel_calculate_chunks(chunks, features, approximate, training_window, verbose, save_progress, entityset, n_jobs, no_unapproximated_aggs, cutoff_df_time_var, target_time, pass_columns, dask_kwargs=None): from distributed import as_completed from dask.base import tokenize client = None cluster = None try: client, cluster = create_client_and_cluster(n_jobs=n_jobs, num_tasks=len(chunks), dask_kwargs=dask_kwargs) # scatter the entityset # denote future with leading underscore start = time.time() es_token = "EntitySet-{}".format(tokenize(entityset)) if es_token in client.list_datasets(): print("Using EntitySet persisted on the cluster as dataset %s" % (es_token)) _es = client.get_dataset(es_token) else: _es = client.scatter([entityset])[0] client.publish_dataset(**{_es.key: _es}) # save features to a tempfile and scatter it pickled_feats = cloudpickle.dumps(features) _saved_features = client.scatter(pickled_feats) client.replicate([_es, _saved_features]) end = time.time() scatter_time = end - start scatter_string = "EntitySet scattered to workers in {:.3f} seconds" print(scatter_string.format(scatter_time)) # map chunks # TODO: consider handling task submission dask kwargs _chunks = client.map(calculate_chunk, chunks, features=_saved_features, entityset=_es, approximate=approximate, training_window=training_window, profile=False, verbose=False, save_progress=save_progress, no_unapproximated_aggs=no_unapproximated_aggs, cutoff_df_time_var=cutoff_df_time_var, target_time=target_time, pass_columns=pass_columns) feature_matrix = [] iterator = as_completed(_chunks).batches() if verbose: pbar_str = ("Elapsed: {elapsed} | Remaining: {remaining} | " "Progress: {l_bar}{bar}| " "Calculated: {n}/{total} chunks") pbar = make_tqdm_iterator(total=len(_chunks), bar_format=pbar_str) for batch in iterator: results = client.gather(batch) for result in results: feature_matrix.append(result) if verbose: pbar.update() if verbose: pbar.close() except Exception: raise finally: if 'cluster' not in dask_kwargs and cluster is not None: cluster.close() if client is not None: client.close() return feature_matrix
def get_pandas_data_slice(self, filter_entity_ids, index_eid, instances, time_last=None, training_window=None, verbose=False): """ Get the slice of data related to the supplied instances of the index entity. """ eframes_by_filter = {} if verbose: iterator = make_tqdm_iterator(iterable=filter_entity_ids, desc="Gathering relevant data", unit="entity") else: iterator = filter_entity_ids # gather frames for each child, for each parent for filter_eid in iterator: # get the instances of the top-level entity linked by our instances toplevel_slice = self._related_instances(start_entity_id=index_eid, final_entity_id=filter_eid, instance_ids=instances, time_last=time_last, training_window=training_window) eframes = {filter_eid: toplevel_slice} # Do a bredth-first search of the relationship tree rooted at this # entity, filling out eframes for each entity we hit on the way. r_queue = self.get_backward_relationships(filter_eid) while r_queue: r = r_queue.pop(0) child_eid = r.child_variable.entity.id parent_eid = r.parent_variable.entity.id # If we've already seen this child, this is a diamond graph and # we don't know what to do if child_eid in eframes: raise RuntimeError('Diamond graph detected!') # Add this child's children to the queue r_queue += self.get_backward_relationships(child_eid) # Query the child of the current backwards relationship for the # instances we want instance_vals = eframes[parent_eid][r.parent_variable.id] eframes[child_eid] =\ self.entity_stores[child_eid].query_by_values( instance_vals, variable_id=r.child_variable.id, time_last=time_last, training_window=training_window) # add link variables to this dataframe in order to link it to its # (grand)parents self._add_multigenerational_link_vars(frames=eframes, start_entity_id=filter_eid, end_entity_id=child_eid) eframes_by_filter[filter_eid] = eframes # If there are no instances of *this* entity in the index, return None if eframes_by_filter[index_eid][index_eid].shape[0] == 0: return None return eframes_by_filter
def calculate_all_features(self, instance_ids, time_last, training_window=None, profile=False, precalculated_features=None, ignored=None, verbose=False): """ Given a list of instance ids and features with a shared time window, generate and return a mapping of instance -> feature values. Args: instance_ids (list): List of instance id for which to build features. time_last (pd.Timestamp): Last allowed time. Data from exactly this time not allowed. training_window (Timedelta, optional): Data older than time_last by more than this will be ignored. profile (bool): Enable profiler if True. verbose (bool): Print output progress if True. Returns: pd.DataFrame : Pandas DataFrame of calculated feature values. Indexed by instance_ids. Columns in same order as features passed in. """ assert len(instance_ids) > 0, "0 instance ids provided" self.instance_ids = instance_ids self.time_last = time_last if self.time_last is None: self.time_last = datetime.now() # For debugging if profile: pr = cProfile.Profile() pr.enable() if precalculated_features is None: precalculated_features = {} # Access the index to get the filtered data we need target_entity = self.entityset[self.target_eid] if ignored: # TODO: Just want to remove entities if don't have any (sub)features defined # on them anymore, rather than recreating ordered_entities = FeatureTree(self.entityset, self.features, ignored=ignored).ordered_entities else: ordered_entities = self.feature_tree.ordered_entities necessary_columns = self.feature_tree.necessary_columns eframes_by_filter = \ self.entityset.get_pandas_data_slice(filter_entity_ids=ordered_entities, index_eid=self.target_eid, instances=instance_ids, entity_columns=necessary_columns, time_last=time_last, training_window=training_window, verbose=verbose) large_eframes_by_filter = None if any([f.uses_full_entity for f in self.feature_tree.all_features]): large_necessary_columns = self.feature_tree.necessary_columns_for_all_values_features large_eframes_by_filter = \ self.entityset.get_pandas_data_slice(filter_entity_ids=ordered_entities, index_eid=self.target_eid, instances=None, entity_columns=large_necessary_columns, time_last=time_last, training_window=training_window, verbose=verbose) # Handle an empty time slice by returning a dataframe with defaults if eframes_by_filter is None: return self.generate_default_df(instance_ids=instance_ids) finished_entity_ids = [] # Populate entity_frames with precalculated features if len(precalculated_features) > 0: for entity_id, precalc_feature_values in precalculated_features.items(): if entity_id in eframes_by_filter: frame = eframes_by_filter[entity_id][entity_id] eframes_by_filter[entity_id][entity_id] = pd.merge(frame, precalc_feature_values, left_index=True, right_index=True) else: # Only features we're taking from this entity # are precomputed # Make sure the id variable is a column as well as an index entity_id_var = self.entityset[entity_id].index precalc_feature_values[entity_id_var] = precalc_feature_values.index.values eframes_by_filter[entity_id] = {entity_id: precalc_feature_values} finished_entity_ids.append(entity_id) # Iterate over the top-level entities (filter entities) in sorted order # and calculate all relevant features under each one. if verbose: total_groups_to_compute = sum(len(group) for group in self.feature_tree.ordered_feature_groups.values()) pbar = make_tqdm_iterator(total=total_groups_to_compute, desc="Computing features", unit="feature group") if verbose: pbar.update(0) for filter_eid in ordered_entities: entity_frames = eframes_by_filter[filter_eid] large_entity_frames = None if large_eframes_by_filter is not None: large_entity_frames = large_eframes_by_filter[filter_eid] # update the current set of entity frames with the computed features # from previously finished entities for eid in finished_entity_ids: # only include this frame if it's not from a descendent entity: # descendent entity frames will have to be re-calculated. # TODO: this check might not be necessary, depending on our # constraints if not self.entityset.find_backward_path(start_entity_id=filter_eid, goal_entity_id=eid): entity_frames[eid] = eframes_by_filter[eid][eid] # TODO: look this over again # precalculated features will only be placed in entity_frames, # and it's possible that that they are the only features computed # for an entity. In this case, the entity won't be present in # large_eframes_by_filter. The relevant lines that this case passes # through are 136-143 if (large_eframes_by_filter is not None and eid in large_eframes_by_filter and eid in large_eframes_by_filter[eid]): large_entity_frames[eid] = large_eframes_by_filter[eid][eid] if filter_eid in self.feature_tree.ordered_feature_groups: for group in self.feature_tree.ordered_feature_groups[filter_eid]: if verbose: pbar.set_postfix({'running': 0}) test_feature = group[0] entity_id = test_feature.entity.id input_frames_type = self.feature_tree.input_frames_type(test_feature) input_frames = large_entity_frames if input_frames_type == "subset_entity_frames": input_frames = entity_frames handler = self._feature_type_handler(test_feature) result_frame = handler(group, input_frames) output_frames_type = self.feature_tree.output_frames_type(test_feature) if output_frames_type in ['full_and_subset_entity_frames', 'subset_entity_frames']: index = entity_frames[entity_id].index # If result_frame came from a uses_full_entity feature, # and the input was large_entity_frames, # then it's possible it doesn't contain some of the features # in the output entity_frames # We thus need to concatenate the existing frame with the result frame, # making sure not to duplicate any columns _result_frame = result_frame.reindex(index) cols_to_keep = [c for c in _result_frame.columns if c not in entity_frames[entity_id].columns] entity_frames[entity_id] = pd.concat([entity_frames[entity_id], _result_frame[cols_to_keep]], axis=1) if output_frames_type in ['full_and_subset_entity_frames', 'full_entity_frames']: index = large_entity_frames[entity_id].index _result_frame = result_frame.reindex(index) cols_to_keep = [c for c in _result_frame.columns if c not in large_entity_frames[entity_id].columns] large_entity_frames[entity_id] = pd.concat([large_entity_frames[entity_id], _result_frame[cols_to_keep]], axis=1) if verbose: pbar.update(1) finished_entity_ids.append(filter_eid) if verbose: pbar.set_postfix({'running': 0}) pbar.refresh() sys.stdout.flush() pbar.close() # debugging if profile: pr.disable() s = io.StringIO() ps = pstats.Stats(pr, stream=s).sort_stats("cumulative", "tottime") ps.print_stats() prof_folder_path = os.path.join(ROOT_DIR, 'prof') if not os.path.exists(prof_folder_path): os.mkdir(prof_folder_path) with open(os.path.join(prof_folder_path, 'inst-%s.log' % list(instance_ids)[0]), 'w') as f: f.write(s.getvalue()) df = eframes_by_filter[self.target_eid][self.target_eid] # fill in empty rows with default values missing_ids = [i for i in instance_ids if i not in df[target_entity.index]] if missing_ids: df = df.append(self.generate_default_df(instance_ids=missing_ids, extra_columns=df.columns)) return df[[feat.get_name() for feat in self.features]]
def build_features(self, variable_types=None, verbose=False): """Automatically builds feature definitions for target entity using Deep Feature Synthesis algorithm Args: variable_types (list[:class:`variable_types.Variable`] or str, optional): Types of variables to return. If None, default to Numeric, Categorical, Ordinal, and Boolean. If given as the string 'all', use all available variable types. verbose (bool, optional): If True, print progress. Returns: list[:class:`.primitives.BaseFeature`]: returns a list of features for target entity, sorted by feature depth (shallow first) """ self.verbose = verbose if verbose: self.pbar = make_tqdm_iterator(desc="Building features") all_features = {} for e in self.es.entities: if e not in self.ignore_entities: all_features[e.id] = {} # add seed features, if any, for dfs to build on top of if self.seed_features is not None: for f in self.seed_features: self._handle_new_feature(all_features=all_features, new_feature=f) self.where_clauses = defaultdict(set) self._run_dfs(self.es[self.target_entity_id], [], all_features, max_depth=self.max_depth) new_features = list(all_features[self.target_entity_id].values()) if variable_types is None: variable_types = [Numeric, Discrete, Boolean] elif variable_types == 'all': variable_types = None else: msg = "variable_types must be a list, or 'all'" assert isinstance(variable_types, list), msg if variable_types is not None: new_features = [ f for f in new_features if any( issubclass(f.variable_type, vt) for vt in variable_types) ] def check_secondary_index(f): secondary_time_index = self.es[ self.target_entity_id].secondary_time_index for s_time_index, exclude in secondary_time_index.items(): if isinstance(f, IdentityFeature) and f.variable.id in exclude: return False elif isinstance(f, (BinaryFeature, Compare)): if (not check_secondary_index(f.left) or not check_secondary_index(f.right)): return False if isinstance(f, TimeSince) and not check_secondary_index( f.base_features[0]): return False return True def filt(f): # remove identity features of the ID field of the target entity if (isinstance(f, IdentityFeature) and f.entity.id == self.target_entity_id and f.variable.id == self.es[self.target_entity_id].index): return False if (isinstance( f, (IdentityFeature, BinaryFeature, Compare, TimeSince)) and not check_secondary_index(f)): return False return True new_features = list(filter(filt, new_features)) # sanity check for duplicate features l = [f.hash() for f in new_features] assert len(set([f for f in l if l.count(f) > 1])) == 0, \ 'Multiple features with same name' + \ str(set([f for f in l if l.count(f) > 1])) new_features.sort(key=lambda f: f.get_depth()) new_features = self._filter_features(new_features) if self.max_features > 0: new_features = new_features[:self.max_features] if verbose: self.pbar.update(0) sys.stdout.flush() self.pbar.close() self.verbose = None return new_features
def parallel_calculate_chunks(chunks, features, approximate, training_window, verbose, save_progress, entityset, n_jobs, no_unapproximated_aggs, cutoff_df_time_var, target_time, pass_columns, dask_kwargs=None): from distributed import as_completed from dask.base import tokenize client = None cluster = None try: client, cluster = create_client_and_cluster(n_jobs=n_jobs, num_tasks=len(chunks), dask_kwargs=dask_kwargs, entityset_size=entityset.__sizeof__()) # scatter the entityset # denote future with leading underscore if verbose: start = time.time() es_token = "EntitySet-{}".format(tokenize(entityset)) if es_token in client.list_datasets(): if verbose: msg = "Using EntitySet persisted on the cluster as dataset {}" print(msg.format(es_token)) _es = client.get_dataset(es_token) else: _es = client.scatter([entityset])[0] client.publish_dataset(**{_es.key: _es}) # save features to a tempfile and scatter it pickled_feats = cloudpickle.dumps(features) _saved_features = client.scatter(pickled_feats) client.replicate([_es, _saved_features]) if verbose: end = time.time() scatter_time = end - start scatter_string = "EntitySet scattered to workers in {:.3f} seconds" print(scatter_string.format(scatter_time)) # map chunks # TODO: consider handling task submission dask kwargs _chunks = client.map(calculate_chunk, chunks, features=_saved_features, entityset=_es, approximate=approximate, training_window=training_window, profile=False, verbose=False, save_progress=save_progress, no_unapproximated_aggs=no_unapproximated_aggs, cutoff_df_time_var=cutoff_df_time_var, target_time=target_time, pass_columns=pass_columns) feature_matrix = [] iterator = as_completed(_chunks).batches() if verbose: pbar_str = ("Elapsed: {elapsed} | Remaining: {remaining} | " "Progress: {l_bar}{bar}| " "Calculated: {n}/{total} chunks") pbar = make_tqdm_iterator(total=len(_chunks), bar_format=pbar_str) for batch in iterator: results = client.gather(batch) for result in results: feature_matrix.append(result) if verbose: pbar.update() if verbose: pbar.close() except Exception: raise finally: if 'cluster' not in dask_kwargs and cluster is not None: cluster.close() if client is not None: client.close() return feature_matrix
def calculate_feature_matrix(features, cutoff_time=None, instance_ids=None, entities=None, relationships=None, entityset=None, cutoff_time_in_index=False, training_window=None, approximate=None, save_progress=None, verbose=False, chunk_size=None, profile=False): """Calculates a matrix for a given set of instance ids and calculation times. Args: features (list[PrimitiveBase]): Feature definitions to be calculated. cutoff_time (pd.DataFrame or Datetime): Specifies at which time to calculate the features for each instance. Can either be a DataFrame with 'instance_id' and 'time' columns, DataFrame with the name of the index variable in the target entity and a time column, a list of values, or a single value to calculate for all instances. If the dataframe has more than two columns, any additional columns will be added to the resulting feature matrix. instance_ids (list): List of instances to calculate features on. Only used if cutoff_time is a single datetime. entities (dict[str -> tuple(pd.DataFrame, str, str)]): dictionary of entities. Entries take the format {entity id: (dataframe, id column, (time_column))}. relationships (list[(str, str, str, str)]): list of relationships between entities. List items are a tuple with the format (parent entity id, parent variable, child entity id, child variable). entityset (EntitySet): An already initialized entityset. Required if entities and relationships are not defined. cutoff_time_in_index (bool): If True, return a DataFrame with a MultiIndex where the second index is the cutoff time (first is instance id). DataFrame will be sorted by (time, instance_id). training_window (dict[str -> Timedelta] or Timedelta, optional): Window or windows defining how much older than the cutoff time data can be to be included when calculating the feature. To specify which entities to apply windows to, use a dictionary mapping entity id -> Timedelta. If None, all older data is used. approximate (Timedelta or str): Frequency to group instances with similar cutoff times by for features with costly calculations. For example, if bucket is 24 hours, all instances with cutoff times on the same day will use the same calculation for expensive features. verbose (bool, optional): Print progress info. The time granularity is per chunk. profile (bool, optional): Enables profiling if True. chunk_size (int or float or None or "cutoff time"): Number of rows of output feature matrix to calculate at time. If passed an integer greater than 0, will try to use that many rows per chunk. If passed a float value between 0 and 1 sets the chunk size to that percentage of all instances. If passed the string "cutoff time", rows are split per cutoff time. save_progress (str, optional): path to save intermediate computational results. """ assert (isinstance(features, list) and features != [] and all([isinstance(feature, PrimitiveBase) for feature in features])), \ "features must be a non-empty list of features" # handle loading entityset from featuretools.entityset.entityset import EntitySet if not isinstance(entityset, EntitySet): if entities is not None and relationships is not None: entityset = EntitySet("entityset", entities, relationships) if entityset is not None: for f in features: f.entityset = entityset entityset = features[0].entityset target_entity = features[0].entity pass_columns = [] if not isinstance(cutoff_time, pd.DataFrame): if cutoff_time is None: if entityset.time_type == NumericTimeIndex: cutoff_time = np.inf else: cutoff_time = datetime.now() if instance_ids is None: index_var = target_entity.index instance_ids = target_entity.df[index_var].tolist() if not isinstance(cutoff_time, list): cutoff_time = [cutoff_time] * len(instance_ids) map_args = [(id, time) for id, time in zip(instance_ids, cutoff_time)] df_args = pd.DataFrame(map_args, columns=['instance_id', 'time']) to_calc = df_args.values cutoff_time = pd.DataFrame(to_calc, columns=['instance_id', 'time']) else: cutoff_time = cutoff_time.copy() # handle how columns are names in cutoff_time if "instance_id" not in cutoff_time.columns: if target_entity.index not in cutoff_time.columns: raise AttributeError('Name of the index variable in the target entity' ' or "instance_id" must be present in cutoff_time') # rename to instance_id cutoff_time.rename(columns={target_entity.index: "instance_id"}, inplace=True) if "time" not in cutoff_time.columns: # take the first column that isn't instance_id and assume it is time not_instance_id = [c for c in cutoff_time.columns if c != "instance_id"] cutoff_time.rename(columns={not_instance_id[0]: "time"}, inplace=True) pass_columns = [column_name for column_name in cutoff_time.columns[2:]] if _check_time_type(cutoff_time['time'].iloc[0]) is None: raise ValueError("cutoff_time time values must be datetime or numeric") backend = PandasBackend(entityset, features) # Get dictionary of features to approximate if approximate is not None: to_approximate, all_approx_feature_set = gather_approximate_features(features, backend) else: to_approximate = defaultdict(list) all_approx_feature_set = None # Check if there are any non-approximated aggregation features no_unapproximated_aggs = True for feature in features: if isinstance(feature, AggregationPrimitive): # do not need to check if feature is in to_approximate since # only base features of direct features can be in to_approximate no_unapproximated_aggs = False break deps = feature.get_deep_dependencies(all_approx_feature_set) for dependency in deps: if (isinstance(dependency, AggregationPrimitive) and dependency not in to_approximate[dependency.entity.id]): no_unapproximated_aggs = False break cutoff_df_time_var = 'time' target_time = '_original_time' num_per_chunk = calc_num_per_chunk(chunk_size, cutoff_time.shape) if approximate is not None: # If there are approximated aggs, bin times binned_cutoff_time = bin_cutoff_times(cutoff_time.copy(), approximate) # Think about collisions: what if original time is a feature binned_cutoff_time[target_time] = cutoff_time[cutoff_df_time_var] cutoff_time_to_pass = binned_cutoff_time else: cutoff_time_to_pass = cutoff_time if num_per_chunk == "cutoff time": iterator = cutoff_time_to_pass.groupby(cutoff_df_time_var) else: iterator = get_next_chunk(cutoff_time=cutoff_time_to_pass, time_variable=cutoff_df_time_var, num_per_chunk=num_per_chunk) # if verbose, create progess bar if verbose: chunks = [] if num_per_chunk == "cutoff time": for _, group in iterator: chunks.append(group) else: for chunk in iterator: chunks.append(chunk) pbar_string = ("Elapsed: {elapsed} | Remaining: {remaining} | " "Progress: {l_bar}{bar}| " "Calculated: {n}/{total} chunks") iterator = make_tqdm_iterator(iterable=chunks, total=len(chunks), bar_format=pbar_string) feature_matrix = [] backend = PandasBackend(entityset, features) for chunk in iterator: # if not using chunks, pull out the group dataframe if isinstance(chunk, tuple): chunk = chunk[1] _feature_matrix = calculate_chunk(features, chunk, approximate, entityset, training_window, profile, verbose, save_progress, backend, no_unapproximated_aggs, cutoff_df_time_var, target_time, pass_columns) feature_matrix.append(_feature_matrix) # Do a manual garbage collection in case objects from calculate_chunk # weren't collected automatically gc.collect() if verbose: iterator.close() feature_matrix = pd.concat(feature_matrix) feature_matrix.sort_index(level='time', kind='mergesort', inplace=True) if not cutoff_time_in_index: feature_matrix.reset_index(level='time', drop=True, inplace=True) if save_progress and os.path.exists(os.path.join(save_progress, 'temp')): shutil.rmtree(os.path.join(save_progress, 'temp')) return feature_matrix
def calculate_feature_matrix(features, entityset=None, cutoff_time=None, instance_ids=None, entities=None, relationships=None, cutoff_time_in_index=False, training_window=None, approximate=None, save_progress=None, verbose=False, chunk_size=None, n_jobs=1, dask_kwargs=None, progress_callback=None, include_cutoff_time=True): """Calculates a matrix for a given set of instance ids and calculation times. Args: features (list[:class:`.FeatureBase`]): Feature definitions to be calculated. entityset (EntitySet): An already initialized entityset. Required if `entities` and `relationships` not provided cutoff_time (pd.DataFrame or Datetime): Specifies times at which to calculate the features for each instance. The resulting feature matrix will use data up to and including the cutoff_time. Can either be a DataFrame or a single value. If a DataFrame is passed the instance ids for which to calculate features must be in a column with the same name as the target entity index or a column named `instance_id`. The cutoff time values in the DataFrame must be in a column with the same name as the target entity time index or a column named `time`. If the DataFrame has more than two columns, any additional columns will be added to the resulting feature matrix. If a single value is passed, this value will be used for all instances. instance_ids (list): List of instances to calculate features on. Only used if cutoff_time is a single datetime. entities (dict[str -> tuple(pd.DataFrame, str, str, dict[str -> Variable])]): dictionary of entities. Entries take the format {entity id -> (dataframe, id column, (time_column), (variable_types))}. Note that time_column and variable_types are optional. relationships (list[(str, str, str, str)]): list of relationships between entities. List items are a tuple with the format (parent entity id, parent variable, child entity id, child variable). cutoff_time_in_index (bool): If True, return a DataFrame with a MultiIndex where the second index is the cutoff time (first is instance id). DataFrame will be sorted by (time, instance_id). training_window (Timedelta or str, 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. Defaults to ``None``. approximate (Timedelta or str): Frequency to group instances with similar cutoff times by for features with costly calculations. For example, if bucket is 24 hours, all instances with cutoff times on the same day will use the same calculation for expensive features. verbose (bool, optional): Print progress info. The time granularity is per chunk. chunk_size (int or float or None): maximum number of rows of output feature matrix to calculate at time. If passed an integer greater than 0, will try to use that many rows per chunk. If passed a float value between 0 and 1 sets the chunk size to that percentage of all rows. if None, and n_jobs > 1 it will be set to 1/n_jobs n_jobs (int, optional): number of parallel processes to use when calculating feature matrix. dask_kwargs (dict, optional): Dictionary of keyword arguments to be passed when creating the dask client and scheduler. Even if n_jobs is not set, using `dask_kwargs` will enable multiprocessing. Main parameters: cluster (str or dask.distributed.LocalCluster): cluster or address of cluster to send tasks to. If unspecified, a cluster will be created. diagnostics port (int): port number to use for web dashboard. If left unspecified, web interface will not be enabled. Valid keyword arguments for LocalCluster will also be accepted. save_progress (str, optional): path to save intermediate computational results. progress_callback (callable): function to be called with incremental progress updates. Has the following parameters: update: percentage change (float between 0 and 100) in progress since last call progress_percent: percentage (float between 0 and 100) of total computation completed time_elapsed: total time in seconds that has elapsed since start of call include_cutoff_time (bool): Include data at cutoff times in feature calculations. Defaults to ``True``. Returns: pd.DataFrame: The feature matrix. """ assert (isinstance(features, list) and features != [] and all([isinstance(feature, FeatureBase) for feature in features])), \ "features must be a non-empty list of features" # handle loading entityset from featuretools.entityset.entityset import EntitySet if not isinstance(entityset, EntitySet): if entities is not None and relationships is not None: entityset = EntitySet("entityset", entities, relationships) if any(isinstance(es.df, dd.DataFrame) for es in entityset.entities): if approximate: msg = "Using approximate is not supported with Dask Entities" raise ValueError(msg) if training_window: msg = "Using training_window is not supported with Dask Entities" raise ValueError(msg) target_entity = entityset[features[0].entity.id] cutoff_time = _validate_cutoff_time(cutoff_time, target_entity) if isinstance(cutoff_time, pd.DataFrame): if instance_ids: msg = "Passing 'instance_ids' is valid only if 'cutoff_time' is a single value or None - ignoring" warnings.warn(msg) pass_columns = [ col for col in cutoff_time.columns if col not in ['instance_id', 'time'] ] # make sure dtype of instance_id in cutoff time # is same as column it references target_entity = features[0].entity dtype = entityset[target_entity.id].df[target_entity.index].dtype cutoff_time["instance_id"] = cutoff_time["instance_id"].astype(dtype) else: pass_columns = [] if cutoff_time is None: if entityset.time_type == NumericTimeIndex: cutoff_time = np.inf else: cutoff_time = datetime.now() if instance_ids is None: index_var = target_entity.index df = target_entity._handle_time( target_entity.df, time_last=cutoff_time, training_window=training_window, include_cutoff_time=include_cutoff_time) instance_ids = df[index_var] if isinstance(instance_ids, dd.Series): instance_ids = instance_ids.compute() elif is_instance(instance_ids, ks, 'Series'): instance_ids = instance_ids.to_pandas() # convert list or range object into series if not isinstance(instance_ids, pd.Series): instance_ids = pd.Series(instance_ids) cutoff_time = (cutoff_time, instance_ids) _check_cutoff_time_type(cutoff_time, entityset.time_type) # Approximate provides no benefit with a single cutoff time, so ignore it if isinstance(cutoff_time, tuple) and approximate is not None: msg = "Using approximate with a single cutoff_time value or no cutoff_time " \ "provides no computational efficiency benefit" warnings.warn(msg) cutoff_time = pd.DataFrame({ "instance_id": cutoff_time[1], "time": [cutoff_time[0]] * len(cutoff_time[1]) }) feature_set = FeatureSet(features) # Get features to approximate if approximate is not None: approximate_feature_trie = gather_approximate_features(feature_set) # Make a new FeatureSet that ignores approximated features feature_set = FeatureSet( features, approximate_feature_trie=approximate_feature_trie) # Check if there are any non-approximated aggregation features no_unapproximated_aggs = True for feature in features: if isinstance(feature, AggregationFeature): # do not need to check if feature is in to_approximate since # only base features of direct features can be in to_approximate no_unapproximated_aggs = False break if approximate is not None: all_approx_features = { f for _, feats in feature_set.approximate_feature_trie for f in feats } else: all_approx_features = set() deps = feature.get_dependencies(deep=True, ignored=all_approx_features) for dependency in deps: if isinstance(dependency, AggregationFeature): no_unapproximated_aggs = False break cutoff_df_time_var = 'time' target_time = '_original_time' if approximate is not None: # If there are approximated aggs, bin times binned_cutoff_time = bin_cutoff_times(cutoff_time, approximate) # Think about collisions: what if original time is a feature binned_cutoff_time[target_time] = cutoff_time[cutoff_df_time_var] cutoff_time_to_pass = binned_cutoff_time else: cutoff_time_to_pass = cutoff_time if isinstance(cutoff_time, pd.DataFrame): cutoff_time_len = cutoff_time.shape[0] else: cutoff_time_len = len(cutoff_time[1]) chunk_size = _handle_chunk_size(chunk_size, cutoff_time_len) tqdm_options = { 'total': (cutoff_time_len / FEATURE_CALCULATION_PERCENTAGE), 'bar_format': PBAR_FORMAT, 'disable': True } if verbose: tqdm_options.update({'disable': False}) elif progress_callback is not None: # allows us to utilize progress_bar updates without printing to anywhere tqdm_options.update({'file': open(os.devnull, 'w'), 'disable': False}) with make_tqdm_iterator(**tqdm_options) as progress_bar: if n_jobs != 1 or dask_kwargs is not None: feature_matrix = parallel_calculate_chunks( cutoff_time=cutoff_time_to_pass, chunk_size=chunk_size, feature_set=feature_set, approximate=approximate, training_window=training_window, save_progress=save_progress, entityset=entityset, n_jobs=n_jobs, no_unapproximated_aggs=no_unapproximated_aggs, cutoff_df_time_var=cutoff_df_time_var, target_time=target_time, pass_columns=pass_columns, progress_bar=progress_bar, dask_kwargs=dask_kwargs or {}, progress_callback=progress_callback, include_cutoff_time=include_cutoff_time) else: feature_matrix = calculate_chunk( cutoff_time=cutoff_time_to_pass, chunk_size=chunk_size, feature_set=feature_set, approximate=approximate, training_window=training_window, save_progress=save_progress, entityset=entityset, no_unapproximated_aggs=no_unapproximated_aggs, cutoff_df_time_var=cutoff_df_time_var, target_time=target_time, pass_columns=pass_columns, progress_bar=progress_bar, progress_callback=progress_callback, include_cutoff_time=include_cutoff_time) # ensure rows are sorted by input order if isinstance(feature_matrix, pd.DataFrame): if isinstance(cutoff_time, pd.DataFrame): feature_matrix = feature_matrix.reindex( pd.MultiIndex.from_frame( cutoff_time[["instance_id", "time"]], names=feature_matrix.index.names)) else: # Maintain index dtype index_dtype = feature_matrix.index.get_level_values(0).dtype feature_matrix = feature_matrix.reindex( cutoff_time[1].astype(index_dtype), level=0) if not cutoff_time_in_index: feature_matrix.reset_index(level='time', drop=True, inplace=True) if save_progress and os.path.exists(os.path.join( save_progress, 'temp')): shutil.rmtree(os.path.join(save_progress, 'temp')) # force to 100% since we saved last 5 percent previous_progress = progress_bar.n progress_bar.update(progress_bar.total - progress_bar.n) if progress_callback is not None: update, progress_percent, time_elapsed = update_progress_callback_parameters( progress_bar, previous_progress) progress_callback(update, progress_percent, time_elapsed) progress_bar.refresh() return feature_matrix
def encode_features(feature_matrix, features, top_n=10, include_unknown=True, to_encode=None, inplace=False, verbose=False): """Encode categorical features Args: feature_matrix (pd.DataFrame): Dataframe of features. features (list[PrimitiveBase]): Feature definitions in feature_matrix. top_n (pd.DataFrame): Number of top values to include. include_unknown (pd.DataFrame): Add feature encoding an unknown class. defaults to True to_encode (list[str]): List of feature names to encode. features not in this list are unencoded in the output matrix defaults to encode all necessary features. inplace (bool): Encode feature_matrix in place. Defaults to False. verbose (str): Print progress info. Returns: (pd.Dataframe, list) : encoded feature_matrix, encoded features Example: .. ipython:: python :suppress: from featuretools.tests.testing_utils import make_ecommerce_entityset import featuretools as ft es = make_ecommerce_entityset() .. ipython:: python f1 = ft.Feature(es["log"]["product_id"]) f2 = ft.Feature(es["log"]["purchased"]) f3 = ft.Feature(es["log"]["value"]) features = [f1, f2, f3] ids = [0, 1, 2, 3, 4, 5] feature_matrix = ft.calculate_feature_matrix(features, es, instance_ids=ids) fm_encoded, f_encoded = ft.encode_features(feature_matrix, features) f_encoded fm_encoded, f_encoded = ft.encode_features(feature_matrix, features, top_n=2) f_encoded fm_encoded, f_encoded = ft.encode_features(feature_matrix, features, include_unknown=False) f_encoded fm_encoded, f_encoded = ft.encode_features(feature_matrix, features, to_encode=['purchased']) f_encoded """ if inplace: X = feature_matrix else: X = feature_matrix.copy() encoded = [] feature_names = [] for feature in features: for fname in feature.get_feature_names(): assert fname in X.columns, ( "Feature %s not found in feature matrix" % (fname) ) feature_names.append(fname) extra_columns = [col for col in X.columns if col not in feature_names] if verbose: iterator = make_tqdm_iterator(iterable=features, total=len(features), desc="Encoding pass 1", unit="feature") else: iterator = features for f in iterator: # TODO: features with multiple columns are not encoded by this method, # which can cause an "encoded" matrix with non-numeric vlaues is_discrete = issubclass(f.variable_type, Discrete) if (f.number_output_features > 1 or not is_discrete): if f.number_output_features > 1: logger.warning("Feature %s has multiple columns and will not " "be encoded. This may result in a matrix with" " non-numeric values." % (f)) encoded.append(f) continue if to_encode is not None and f.get_name() not in to_encode: encoded.append(f) continue val_counts = X[f.get_name()].value_counts().to_frame() index_name = val_counts.index.name if index_name is None: if 'index' in val_counts.columns: index_name = 'level_0' else: index_name = 'index' val_counts.reset_index(inplace=True) val_counts = val_counts.sort_values([f.get_name(), index_name], ascending=False) val_counts.set_index(index_name, inplace=True) unique = val_counts.head(top_n).index.tolist() for label in unique: add = f == label encoded.append(add) X[add.get_name()] = (X[f.get_name()] == label).astype(int) if include_unknown: unknown = f.isin(unique).NOT().rename(f.get_name() + " is unknown") encoded.append(unknown) X[unknown.get_name()] = (~X[f.get_name()].isin(unique)).astype(int) X.drop(f.get_name(), axis=1, inplace=True) new_columns = [] for e in encoded: new_columns.extend(e.get_feature_names()) new_columns.extend(extra_columns) new_X = X[new_columns] iterator = new_X.columns if verbose: iterator = make_tqdm_iterator(iterable=new_X.columns, total=len(new_X.columns), desc="Encoding pass 2", unit="feature") for c in iterator: if c in extra_columns: continue try: new_X[c] = pd.to_numeric(new_X[c], errors='raise') except (TypeError, ValueError): pass return new_X, encoded
def encode_features(feature_matrix, features, top_n=10, include_unknown=True, to_encode=None, inplace=False, verbose=False): """Encode categorical features Args: feature_matrix (pd.DataFrame): Dataframe of features. features (list[PrimitiveBase]): Feature definitions in feature_matrix. top_n (pd.DataFrame): Number of top values to include. include_unknown (pd.DataFrame): Add feature encoding an unkwown class. defaults to True to_encode (list[str]): List of feature names to encode. features not in this list are unencoded in the output matrix defaults to encode all necessary features. inplace (bool): Encode feature_matrix in place. Defaults to False. verbose (str): Print progress info. Returns: (pd.Dataframe, list) : encoded feature_matrix, encoded features Example: .. ipython:: python :suppress: from featuretools.tests.testing_utils import make_ecommerce_entityset from featuretools.primitives import Feature import featuretools as ft es = make_ecommerce_entityset() .. ipython:: python f1 = Feature(es["log"]["product_id"]) f2 = Feature(es["log"]["purchased"]) f3 = Feature(es["log"]["value"]) features = [f1, f2, f3] ids = [0, 1, 2, 3, 4, 5] feature_matrix = ft.calculate_feature_matrix(features, es, instance_ids=ids) fm_encoded, f_encoded = ft.encode_features(feature_matrix, features) f_encoded fm_encoded, f_encoded = ft.encode_features(feature_matrix, features, top_n=2) f_encoded fm_encoded, f_encoded = ft.encode_features(feature_matrix, features, include_unknown=False) f_encoded fm_encoded, f_encoded = ft.encode_features(feature_matrix, features, to_encode=['purchased']) f_encoded """ if inplace: X = feature_matrix else: X = feature_matrix.copy() encoded = [] feature_names = [] for feature in features: fname = feature.get_name() assert fname in X.columns, ( "Feature %s not found in feature matrix" % (fname) ) feature_names.append(fname) extra_columns = [col for col in X.columns if col not in feature_names] if verbose: iterator = make_tqdm_iterator(iterable=features, total=len(features), desc="Encoding pass 1", unit="feature") else: iterator = features for f in iterator: if (f.expanding or (not issubclass(f.variable_type, Discrete))): encoded.append(f) continue if to_encode is not None and f.get_name() not in to_encode: encoded.append(f) continue val_counts = X[f.get_name()].value_counts().to_frame() index_name = val_counts.index.name if index_name is None: if 'index' in val_counts.columns: index_name = 'level_0' else: index_name = 'index' val_counts.reset_index(inplace=True) val_counts = val_counts.sort_values([f.get_name(), index_name], ascending=False) val_counts.set_index(index_name, inplace=True) unique = val_counts.head(top_n).index.tolist() for label in unique: add = f == label encoded.append(add) X[add.get_name()] = (X[f.get_name()] == label).astype(int) if include_unknown: unknown = f.isin(unique).NOT().rename(f.get_name() + " = unknown") encoded.append(unknown) X[unknown.get_name()] = (~X[f.get_name()].isin(unique)).astype(int) X.drop(f.get_name(), axis=1, inplace=True) new_X = X[[e.get_name() for e in encoded] + extra_columns] iterator = new_X.columns if verbose: iterator = make_tqdm_iterator(iterable=new_X.columns, total=len(new_X.columns), desc="Encoding pass 2", unit="feature") for c in iterator: if c in extra_columns: continue try: new_X[c] = pd.to_numeric(new_X[c], errors='raise') except (TypeError, ValueError): pass return new_X, encoded
def encode_features( feature_matrix, features, top_n=DEFAULT_TOP_N, include_unknown=True, to_encode=None, inplace=False, drop_first=False, verbose=False, ): """Encode categorical features Args: feature_matrix (pd.DataFrame): Dataframe of features. features (list[PrimitiveBase]): Feature definitions in feature_matrix. top_n (int or dict[string -> int]): Number of top values to include. If dict[string -> int] is used, key is feature name and value is the number of top values to include for that feature. If a feature's name is not in dictionary, a default value of 10 is used. include_unknown (pd.DataFrame): Add feature encoding an unknown class. defaults to True to_encode (list[str]): List of feature names to encode. features not in this list are unencoded in the output matrix defaults to encode all necessary features. inplace (bool): Encode feature_matrix in place. Defaults to False. drop_first (bool): Whether to get k-1 dummies out of k categorical levels by removing the first level. defaults to False verbose (str): Print progress info. Returns: (pd.Dataframe, list) : encoded feature_matrix, encoded features Example: .. ipython:: python :suppress: from featuretools.tests.testing_utils import make_ecommerce_entityset import featuretools as ft es = make_ecommerce_entityset() .. ipython:: python f1 = ft.Feature(es["log"].ww["product_id"]) f2 = ft.Feature(es["log"].ww["purchased"]) f3 = ft.Feature(es["log"].ww["value"]) features = [f1, f2, f3] ids = [0, 1, 2, 3, 4, 5] feature_matrix = ft.calculate_feature_matrix(features, es, instance_ids=ids) fm_encoded, f_encoded = ft.encode_features(feature_matrix, features) f_encoded fm_encoded, f_encoded = ft.encode_features(feature_matrix, features, top_n=2) f_encoded fm_encoded, f_encoded = ft.encode_features(feature_matrix, features, include_unknown=False) f_encoded fm_encoded, f_encoded = ft.encode_features(feature_matrix, features, to_encode=['purchased']) f_encoded fm_encoded, f_encoded = ft.encode_features(feature_matrix, features, drop_first=True) f_encoded """ if not isinstance(feature_matrix, pd.DataFrame): msg = "feature_matrix must be a Pandas DataFrame" raise TypeError(msg) if inplace: X = feature_matrix else: X = feature_matrix.copy() old_feature_names = set() for feature in features: for fname in feature.get_feature_names(): assert fname in X.columns, "Feature %s not found in feature matrix" % ( fname) old_feature_names.add(fname) pass_through = [col for col in X.columns if col not in old_feature_names] if verbose: iterator = make_tqdm_iterator( iterable=features, total=len(features), desc="Encoding pass 1", unit="feature", ) else: iterator = features new_feature_list = [] kept_columns = [] encoded_columns = [] columns_info = feature_matrix.ww.columns for f in iterator: # TODO: features with multiple columns are not encoded by this method, # which can cause an "encoded" matrix with non-numeric values is_discrete = {"category", "foreign_key" }.intersection(f.column_schema.semantic_tags) if f.number_output_features > 1 or not is_discrete: if f.number_output_features > 1: logger.warning("Feature %s has multiple columns and will not " "be encoded. This may result in a matrix with" " non-numeric values." % (f)) new_feature_list.append(f) kept_columns.extend(f.get_feature_names()) continue if to_encode is not None and f.get_name() not in to_encode: new_feature_list.append(f) kept_columns.extend(f.get_feature_names()) continue val_counts = X[f.get_name()].value_counts() # Remove 0 count category values val_counts = val_counts[val_counts > 0].to_frame() index_name = val_counts.index.name if index_name is None: if "index" in val_counts.columns: index_name = "level_0" else: index_name = "index" val_counts.reset_index(inplace=True) val_counts = val_counts.sort_values([f.get_name(), index_name], ascending=False) val_counts.set_index(index_name, inplace=True) select_n = top_n if isinstance(top_n, dict): select_n = top_n.get(f.get_name(), DEFAULT_TOP_N) if drop_first: select_n = min(len(val_counts), top_n) select_n = max(select_n - 1, 1) unique = val_counts.head(select_n).index.tolist() for label in unique: add = f == label add_name = add.get_name() new_feature_list.append(add) new_col = X[f.get_name()] == label new_col.rename(add_name, inplace=True) encoded_columns.append(new_col) if include_unknown: unknown = f.isin(unique).NOT().rename(f.get_name() + " is unknown") unknown_name = unknown.get_name() new_feature_list.append(unknown) new_col = ~X[f.get_name()].isin(unique) new_col.rename(unknown_name, inplace=True) encoded_columns.append(new_col) if inplace: X.drop(f.get_name(), axis=1, inplace=True) kept_columns.extend(pass_through) if inplace: for encoded_column in encoded_columns: X[encoded_column.name] = encoded_column else: X = pd.concat([X[kept_columns]] + encoded_columns, axis=1) entityset = new_feature_list[0].entityset ww_init_kwargs = get_ww_types_from_features(new_feature_list, entityset) # Grab ww metadata from feature matrix since it may be more exact for column in kept_columns: ww_init_kwargs["logical_types"][column] = columns_info[ column].logical_type ww_init_kwargs["semantic_tags"][column] = columns_info[ column].semantic_tags ww_init_kwargs["column_origins"][column] = columns_info[column].origin X.ww.init(**ww_init_kwargs) return X, new_feature_list
def calculate_feature_matrix(features, entityset=None, cutoff_time=None, instance_ids=None, entities=None, relationships=None, cutoff_time_in_index=False, training_window=None, approximate=None, save_progress=None, verbose=False, chunk_size=None, n_jobs=1, dask_kwargs=None, progress_callback=None): """Calculates a matrix for a given set of instance ids and calculation times. Args: features (list[:class:`.FeatureBase`]): Feature definitions to be calculated. entityset (EntitySet): An already initialized entityset. Required if `entities` and `relationships` not provided cutoff_time (pd.DataFrame or Datetime): Specifies at which time to calculate the features for each instance. The resulting feature matrix will use data up to and including the cutoff_time. Can either be a DataFrame with 'instance_id' and 'time' columns, DataFrame with the name of the index variable in the target entity and a time column, or a single value to calculate for all instances. If the dataframe has more than two columns, any additional columns will be added to the resulting feature matrix. instance_ids (list): List of instances to calculate features on. Only used if cutoff_time is a single datetime. entities (dict[str -> tuple(pd.DataFrame, str, str)]): dictionary of entities. Entries take the format {entity id: (dataframe, id column, (time_column))}. relationships (list[(str, str, str, str)]): list of relationships between entities. List items are a tuple with the format (parent entity id, parent variable, child entity id, child variable). cutoff_time_in_index (bool): If True, return a DataFrame with a MultiIndex where the second index is the cutoff time (first is instance id). DataFrame will be sorted by (time, instance_id). training_window (Timedelta or str, 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. Defaults to ``None``. approximate (Timedelta or str): Frequency to group instances with similar cutoff times by for features with costly calculations. For example, if bucket is 24 hours, all instances with cutoff times on the same day will use the same calculation for expensive features. verbose (bool, optional): Print progress info. The time granularity is per chunk. chunk_size (int or float or None): maximum number of rows of output feature matrix to calculate at time. If passed an integer greater than 0, will try to use that many rows per chunk. If passed a float value between 0 and 1 sets the chunk size to that percentage of all rows. if None, and n_jobs > 1 it will be set to 1/n_jobs n_jobs (int, optional): number of parallel processes to use when calculating feature matrix. dask_kwargs (dict, optional): Dictionary of keyword arguments to be passed when creating the dask client and scheduler. Even if n_jobs is not set, using `dask_kwargs` will enable multiprocessing. Main parameters: cluster (str or dask.distributed.LocalCluster): cluster or address of cluster to send tasks to. If unspecified, a cluster will be created. diagnostics port (int): port number to use for web dashboard. If left unspecified, web interface will not be enabled. Valid keyword arguments for LocalCluster will also be accepted. save_progress (str, optional): path to save intermediate computational results. progress_callback (callable): function to be called with incremental progress updates. Has the following parameters: update: percentage change (float between 0 and 100) in progress since last call progress_percent: percentage (float between 0 and 100) of total computation completed time_elapsed: total time in seconds that has elapsed since start of call """ assert (isinstance(features, list) and features != [] and all([isinstance(feature, FeatureBase) for feature in features])), \ "features must be a non-empty list of features" # handle loading entityset from featuretools.entityset.entityset import EntitySet if not isinstance(entityset, EntitySet): if entities is not None and relationships is not None: entityset = EntitySet("entityset", entities, relationships) target_entity = entityset[features[0].entity.id] pass_columns = [] if not isinstance(cutoff_time, pd.DataFrame): if isinstance(cutoff_time, list): raise TypeError("cutoff_time must be a single value or DataFrame") if cutoff_time is None: if entityset.time_type == NumericTimeIndex: cutoff_time = np.inf else: cutoff_time = datetime.now() if instance_ids is None: index_var = target_entity.index df = target_entity._handle_time(target_entity.df, time_last=cutoff_time, training_window=training_window) instance_ids = df[index_var].tolist() cutoff_time = [cutoff_time] * len(instance_ids) map_args = [(id, time) for id, time in zip(instance_ids, cutoff_time)] cutoff_time = pd.DataFrame(map_args, columns=['instance_id', 'time']) cutoff_time = cutoff_time.reset_index(drop=True) # handle how columns are names in cutoff_time # maybe add _check_time_dtype helper function if "instance_id" not in cutoff_time.columns: if target_entity.index not in cutoff_time.columns: raise AttributeError( 'Name of the index variable in the target entity' ' or "instance_id" must be present in cutoff_time') # rename to instance_id cutoff_time.rename(columns={target_entity.index: "instance_id"}, inplace=True) if "time" not in cutoff_time.columns: # take the first column that isn't instance_id and assume it is time not_instance_id = [ c for c in cutoff_time.columns if c != "instance_id" ] cutoff_time.rename(columns={not_instance_id[0]: "time"}, inplace=True) # Check that cutoff_time time type matches entityset time type if entityset.time_type == NumericTimeIndex: if cutoff_time['time'].dtype.name not in PandasTypes._pandas_numerics: raise TypeError("cutoff_time times must be numeric: try casting " "via pd.to_numeric(cutoff_time['time'])") elif entityset.time_type == DatetimeTimeIndex: if cutoff_time['time'].dtype.name not in PandasTypes._pandas_datetimes: raise TypeError( "cutoff_time times must be datetime type: try casting via pd.to_datetime(cutoff_time['time'])" ) assert (cutoff_time[['instance_id', 'time']].duplicated().sum() == 0), \ "Duplicated rows in cutoff time dataframe." pass_columns = [column_name for column_name in cutoff_time.columns[2:]] if _check_time_type(cutoff_time['time'].iloc[0]) is None: raise ValueError("cutoff_time time values must be datetime or numeric") # make sure dtype of instance_id in cutoff time # is same as column it references target_entity = features[0].entity dtype = entityset[target_entity.id].df[target_entity.index].dtype cutoff_time["instance_id"] = cutoff_time["instance_id"].astype(dtype) feature_set = FeatureSet(features) # Get features to approximate if approximate is not None: approximate_feature_trie = gather_approximate_features(feature_set) # Make a new FeatureSet that ignores approximated features feature_set = FeatureSet( features, approximate_feature_trie=approximate_feature_trie) # Check if there are any non-approximated aggregation features no_unapproximated_aggs = True for feature in features: if isinstance(feature, AggregationFeature): # do not need to check if feature is in to_approximate since # only base features of direct features can be in to_approximate no_unapproximated_aggs = False break if approximate is not None: all_approx_features = { f for _, feats in feature_set.approximate_feature_trie for f in feats } else: all_approx_features = set() deps = feature.get_dependencies(deep=True, ignored=all_approx_features) for dependency in deps: if isinstance(dependency, AggregationFeature): no_unapproximated_aggs = False break cutoff_df_time_var = 'time' target_time = '_original_time' if approximate is not None: # If there are approximated aggs, bin times binned_cutoff_time = bin_cutoff_times(cutoff_time.copy(), approximate) # Think about collisions: what if original time is a feature binned_cutoff_time[target_time] = cutoff_time[cutoff_df_time_var] cutoff_time_to_pass = binned_cutoff_time else: cutoff_time_to_pass = cutoff_time chunk_size = _handle_chunk_size(chunk_size, cutoff_time.shape[0]) tqdm_options = { 'total': (cutoff_time.shape[0] / FEATURE_CALCULATION_PERCENTAGE), 'bar_format': PBAR_FORMAT, 'disable': True } if verbose: tqdm_options.update({'disable': False}) elif progress_callback is not None: # allows us to utilize progress_bar updates without printing to anywhere tqdm_options.update({'file': open(os.devnull, 'w'), 'disable': False}) progress_bar = make_tqdm_iterator(**tqdm_options) if n_jobs != 1 or dask_kwargs is not None: feature_matrix = parallel_calculate_chunks( cutoff_time=cutoff_time_to_pass, chunk_size=chunk_size, feature_set=feature_set, approximate=approximate, training_window=training_window, save_progress=save_progress, entityset=entityset, n_jobs=n_jobs, no_unapproximated_aggs=no_unapproximated_aggs, cutoff_df_time_var=cutoff_df_time_var, target_time=target_time, pass_columns=pass_columns, progress_bar=progress_bar, dask_kwargs=dask_kwargs or {}, progress_callback=progress_callback) else: feature_matrix = calculate_chunk( cutoff_time=cutoff_time_to_pass, chunk_size=chunk_size, feature_set=feature_set, approximate=approximate, training_window=training_window, save_progress=save_progress, entityset=entityset, no_unapproximated_aggs=no_unapproximated_aggs, cutoff_df_time_var=cutoff_df_time_var, target_time=target_time, pass_columns=pass_columns, progress_bar=progress_bar, progress_callback=progress_callback) # ensure rows are sorted by input order feature_matrix = feature_matrix.reindex( cutoff_time[["instance_id", "time"]]) if not cutoff_time_in_index: feature_matrix.reset_index(level='time', drop=True, inplace=True) if save_progress and os.path.exists(os.path.join(save_progress, 'temp')): shutil.rmtree(os.path.join(save_progress, 'temp')) # force to 100% since we saved last 5 percent previous_progress = progress_bar.n progress_bar.update(progress_bar.total - progress_bar.n) if progress_callback is not None: update, progress_percent, time_elapsed = update_progress_callback_parameters( progress_bar, previous_progress) progress_callback(update, progress_percent, time_elapsed) progress_bar.refresh() progress_bar.close() return feature_matrix
def calculate_feature_matrix(features, entityset=None, cutoff_time=None, instance_ids=None, entities=None, relationships=None, cutoff_time_in_index=False, training_window=None, approximate=None, save_progress=None, verbose=False, chunk_size=None, profile=False): """Calculates a matrix for a given set of instance ids and calculation times. Args: features (list[PrimitiveBase]): Feature definitions to be calculated. entityset (EntitySet): An already initialized entityset. Required if `entities` and `relationships` not provided cutoff_time (pd.DataFrame or Datetime): Specifies at which time to calculate the features for each instance. Can either be a DataFrame with 'instance_id' and 'time' columns, DataFrame with the name of the index variable in the target entity and a time column, or a single value to calculate for all instances. If the dataframe has more than two columns, any additional columns will be added to the resulting feature matrix. instance_ids (list): List of instances to calculate features on. Only used if cutoff_time is a single datetime. entities (dict[str -> tuple(pd.DataFrame, str, str)]): dictionary of entities. Entries take the format {entity id: (dataframe, id column, (time_column))}. relationships (list[(str, str, str, str)]): list of relationships between entities. List items are a tuple with the format (parent entity id, parent variable, child entity id, child variable). cutoff_time_in_index (bool): If True, return a DataFrame with a MultiIndex where the second index is the cutoff time (first is instance id). DataFrame will be sorted by (time, instance_id). training_window (dict[str -> Timedelta] or Timedelta, optional): Window or windows defining how much older than the cutoff time data can be to be included when calculating the feature. To specify which entities to apply windows to, use a dictionary mapping entity id -> Timedelta. If None, all older data is used. approximate (Timedelta or str): Frequency to group instances with similar cutoff times by for features with costly calculations. For example, if bucket is 24 hours, all instances with cutoff times on the same day will use the same calculation for expensive features. verbose (bool, optional): Print progress info. The time granularity is per chunk. profile (bool, optional): Enables profiling if True. chunk_size (int or float or None or "cutoff time"): Number of rows of output feature matrix to calculate at time. If passed an integer greater than 0, will try to use that many rows per chunk. If passed a float value between 0 and 1 sets the chunk size to that percentage of all instances. If passed the string "cutoff time", rows are split per cutoff time. save_progress (str, optional): path to save intermediate computational results. """ assert (isinstance(features, list) and features != [] and all([isinstance(feature, PrimitiveBase) for feature in features])), \ "features must be a non-empty list of features" # handle loading entityset from featuretools.entityset.entityset import EntitySet if not isinstance(entityset, EntitySet): if entities is not None and relationships is not None: entityset = EntitySet("entityset", entities, relationships) target_entity = entityset[features[0].entity.id] pass_columns = [] if not isinstance(cutoff_time, pd.DataFrame): if isinstance(cutoff_time, list): raise TypeError("cutoff_time must be a single value or DataFrame") if cutoff_time is None: if entityset.time_type == NumericTimeIndex: cutoff_time = np.inf else: cutoff_time = datetime.now() if instance_ids is None: index_var = target_entity.index instance_ids = target_entity.df[index_var].tolist() cutoff_time = [cutoff_time] * len(instance_ids) map_args = [(id, time) for id, time in zip(instance_ids, cutoff_time)] cutoff_time = pd.DataFrame(map_args, columns=['instance_id', 'time']) else: cutoff_time = cutoff_time.copy() # handle how columns are names in cutoff_time if "instance_id" not in cutoff_time.columns: if target_entity.index not in cutoff_time.columns: raise AttributeError( 'Name of the index variable in the target entity' ' or "instance_id" must be present in cutoff_time') # rename to instance_id cutoff_time.rename(columns={target_entity.index: "instance_id"}, inplace=True) if "time" not in cutoff_time.columns: # take the first column that isn't instance_id and assume it is time not_instance_id = [ c for c in cutoff_time.columns if c != "instance_id" ] cutoff_time.rename(columns={not_instance_id[0]: "time"}, inplace=True) if cutoff_time['time'].dtype == object: if (entityset.time_type == NumericTimeIndex and cutoff_time['time'].dtype.name.find('int') == -1 and cutoff_time['time'].dtype.name.find('float') == -1): raise TypeError( "cutoff_time times must be numeric: try casting via pd.to_numeric(cutoff_time['time'])" ) elif (entityset.time_type == DatetimeTimeIndex and cutoff_time['time'].dtype.name.find('time') == -1): raise TypeError( "cutoff_time times must be datetime type: try casting via pd.to_datetime(cutoff_time['time'])" ) pass_columns = [column_name for column_name in cutoff_time.columns[2:]] if _check_time_type(cutoff_time['time'].iloc[0]) is None: raise ValueError("cutoff_time time values must be datetime or numeric") backend = PandasBackend(entityset, features) # Get dictionary of features to approximate if approximate is not None: to_approximate, all_approx_feature_set = gather_approximate_features( features, backend) else: to_approximate = defaultdict(list) all_approx_feature_set = None # Check if there are any non-approximated aggregation features no_unapproximated_aggs = True for feature in features: if isinstance(feature, AggregationPrimitive): # do not need to check if feature is in to_approximate since # only base features of direct features can be in to_approximate no_unapproximated_aggs = False break deps = feature.get_deep_dependencies(all_approx_feature_set) for dependency in deps: if (isinstance(dependency, AggregationPrimitive) and dependency not in to_approximate[dependency.entity.id]): no_unapproximated_aggs = False break cutoff_df_time_var = 'time' target_time = '_original_time' num_per_chunk = calc_num_per_chunk(chunk_size, cutoff_time.shape) if approximate is not None: # If there are approximated aggs, bin times binned_cutoff_time = bin_cutoff_times(cutoff_time.copy(), approximate) # Think about collisions: what if original time is a feature binned_cutoff_time[target_time] = cutoff_time[cutoff_df_time_var] cutoff_time_to_pass = binned_cutoff_time else: cutoff_time_to_pass = cutoff_time if num_per_chunk == "cutoff time": iterator = cutoff_time_to_pass.groupby(cutoff_df_time_var) else: iterator = get_next_chunk(cutoff_time=cutoff_time_to_pass, time_variable=cutoff_df_time_var, num_per_chunk=num_per_chunk) # if verbose, create progess bar if verbose: chunks = [] if num_per_chunk == "cutoff time": for _, group in iterator: chunks.append(group) else: for chunk in iterator: chunks.append(chunk) pbar_string = ("Elapsed: {elapsed} | Remaining: {remaining} | " "Progress: {l_bar}{bar}| " "Calculated: {n}/{total} chunks") iterator = make_tqdm_iterator(iterable=chunks, total=len(chunks), bar_format=pbar_string) feature_matrix = [] backend = PandasBackend(entityset, features) for chunk in iterator: # if not using chunks, pull out the group dataframe if isinstance(chunk, tuple): chunk = chunk[1] _feature_matrix = calculate_chunk(features, chunk, approximate, entityset, training_window, profile, verbose, save_progress, backend, no_unapproximated_aggs, cutoff_df_time_var, target_time, pass_columns) feature_matrix.append(_feature_matrix) # Do a manual garbage collection in case objects from calculate_chunk # weren't collected automatically gc.collect() if verbose: iterator.close() feature_matrix = pd.concat(feature_matrix) feature_matrix.sort_index(level='time', kind='mergesort', inplace=True) if not cutoff_time_in_index: feature_matrix.reset_index(level='time', drop=True, inplace=True) if save_progress and os.path.exists(os.path.join(save_progress, 'temp')): shutil.rmtree(os.path.join(save_progress, 'temp')) return feature_matrix
def get_pandas_data_slice(self, filter_entity_ids, index_eid, instances, entity_columns=None, time_last=None, training_window=None, verbose=False): """ Get the slice of data related to the supplied instances of the index entity. """ eframes_by_filter = {} if verbose: iterator = make_tqdm_iterator(iterable=filter_entity_ids, desc="Gathering relevant data", unit="entity") else: iterator = filter_entity_ids # gather frames for each child, for each parent for filter_eid in iterator: # get the instances of the top-level entity linked by our instances toplevel_slice = self._related_instances(start_entity_id=index_eid, final_entity_id=filter_eid, instance_ids=instances, time_last=time_last, training_window=training_window) eframes = {filter_eid: toplevel_slice} # Do a bredth-first search of the relationship tree rooted at this # entity, filling out eframes for each entity we hit on the way. r_queue = self.get_backward_relationships(filter_eid) while r_queue: r = r_queue.pop(0) child_eid = r.child_variable.entity.id child_columns = None if entity_columns is not None and child_eid not in entity_columns: # entity_columns specifies which columns to extract # if it skips a relationship (specifies child and grandparent columns) # we need to at least add the ids of the intermediate entity child_columns = [v.id for v in self[child_eid].variables if isinstance(v, (vtypes.Index, vtypes.Id, vtypes.TimeIndex))] elif entity_columns is not None: child_columns = entity_columns[child_eid] parent_eid = r.parent_variable.entity.id # If we've already seen this child, this is a diamond graph and # we don't know what to do if child_eid in eframes: raise RuntimeError('Diamond graph detected!') # Add this child's children to the queue r_queue += self.get_backward_relationships(child_eid) # Query the child of the current backwards relationship for the # instances we want instance_vals = eframes[parent_eid][r.parent_variable.id] eframes[child_eid] =\ self.entity_stores[child_eid].query_by_values( instance_vals, variable_id=r.child_variable.id, columns=child_columns, time_last=time_last, training_window=training_window) # add link variables to this dataframe in order to link it to its # (grand)parents self._add_multigenerational_link_vars(frames=eframes, start_entity_id=filter_eid, end_entity_id=child_eid) eframes_by_filter[filter_eid] = eframes # If there are no instances of *this* entity in the index, return None if eframes_by_filter[index_eid][index_eid].shape[0] == 0: return None return eframes_by_filter