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import functools |
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import os |
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import re |
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from collections import OrderedDict |
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from typing import Dict, List, Optional |
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import duckdb |
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import pandas as pd |
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import torch |
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from .tables import ed_cxr_token_type_ids, ed_module_tables, mimic_cxr_tables |
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def mimic_cxr_text_path(dir, subject_id, study_id, ext='txt'): |
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return os.path.join(dir, 'p' + str(subject_id)[:2], 'p' + str(subject_id), |
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's' + str(study_id) + '.' + ext) |
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def format(text): |
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text = re.sub(r'\n|\t', ' ', text) |
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text = re.sub(r'\s+', ' ', text) |
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text = text.strip() |
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return text |
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def rgetattr(obj, attr, *args): |
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def _getattr(obj, attr): |
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return getattr(obj, attr, *args) |
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return functools.reduce(_getattr, [obj] + attr.split('.')) |
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def df_to_tensor_index_columns( |
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df: pd.DataFrame, |
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tensor: torch.Tensor, |
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group_idx_to_y_idx: Dict, |
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groupby: str, |
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index_columns: List[str], |
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): |
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""" |
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Converts a dataframe with index columns to a tensor, where each index of the y-axis is determined by the |
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'groupby' column. |
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""" |
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assert len(group_idx_to_y_idx) == tensor.shape[0] |
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all_columns = index_columns + [groupby] |
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y_indices = [group_idx_to_y_idx[row[groupby]] for _, row in df[all_columns].iterrows() for i in index_columns if row[i] == row[i]] |
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x_indices = [row[i] for _, row in df[all_columns].iterrows() for i in index_columns if row[i] == row[i]] |
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tensor[y_indices, x_indices] = 1.0 |
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return tensor |
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def df_to_tensor_value_columns( |
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df: pd.DataFrame, |
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tensor: torch.Tensor, |
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group_idx_to_y_idx: Dict, |
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groupby: str, |
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value_columns: List[str], |
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value_column_to_idx: Dict, |
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): |
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""" |
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Converts a dataframe with value columns to a tensor, where each index of the y-axis is determined by the |
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'groupby' column. The x-index is determined by a dictionary using the column name. |
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""" |
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assert len(group_idx_to_y_idx) == tensor.shape[0] |
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all_columns = value_columns + [groupby] |
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y_indices = [group_idx_to_y_idx[row[groupby]] for _, row in df[all_columns].iterrows() for i in value_columns if row[i] == row[i]] |
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x_indices = [value_column_to_idx[i] for _, row in df[all_columns].iterrows() for i in value_columns if row[i] == row[i]] |
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element_value = [row[i] for _, row in df[all_columns].iterrows() for i in value_columns if row[i] == row[i]] |
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tensor[y_indices, x_indices] = torch.tensor(element_value, dtype=tensor.dtype) |
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return tensor |
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class EDCXRSubjectRecords: |
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def __init__( |
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self, |
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database_path: str, |
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dataset_dir: Optional[str] = None, |
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reports_dir: Optional[str] = None, |
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token_type_ids_starting_idx: Optional[int] = None, |
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time_delta_map = lambda x: x, |
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debug: bool = False |
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): |
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self.database_path = database_path |
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self.dataset_dir = dataset_dir |
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self.reports_dir = reports_dir |
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self.time_delta_map = time_delta_map |
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self.debug = debug |
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self.connect = duckdb.connect(self.database_path, read_only=True) |
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self.streamlit_flag = False |
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self.clear_start_end_times() |
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self.ed_module_tables = ed_module_tables |
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self.mimic_cxr_tables = mimic_cxr_tables |
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lut_info = self.connect.sql("FROM lut_info").df() |
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for k, v in (self.ed_module_tables | self.mimic_cxr_tables).items(): |
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if v.load and (v.value_columns or v.index_columns): |
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v.value_column_to_idx = {} |
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if v.index_columns: |
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v.total_indices = lut_info[lut_info['table_name'] == k]['end_index'].item() + 1 |
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else: |
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v.total_indices = 0 |
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for i in v.value_columns: |
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v.value_column_to_idx[i] = v.total_indices |
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v.total_indices += 1 |
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self.token_type_to_token_type_id = ed_cxr_token_type_ids |
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if token_type_ids_starting_idx is not None: |
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self.token_type_to_token_type_id = {k: v + token_type_ids_starting_idx for k, v in self.token_type_to_token_type_id.items()} |
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def __len__(self): |
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return len(self.subject_ids) |
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def clear_start_end_times(self): |
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self.start_time, self.end_time = None, None |
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def admission_ed_stay_ids(self, hadm_id): |
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if hadm_id: |
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return self.connect.sql(f'SELECT stay_id FROM edstays WHERE subject_id = {self.subject_id} AND hadm_id = {hadm_id}').df()['stay_id'].tolist() |
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else: |
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return self.connect.sql(f'SELECT stay_id FROM edstays WHERE subject_id = {self.subject_id}').df()['stay_id'].tolist() |
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def subject_study_ids(self): |
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mimic_cxr = self.connect.sql( |
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f'SELECT study_id, study_datetime FROM mimic_cxr WHERE subject_id = {self.subject_id}', |
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).df() |
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if self.start_time and self.end_time: |
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mimic_cxr = self.filter_admissions_by_time_span(mimic_cxr, 'study_datetime') |
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mimic_cxr = mimic_cxr.drop_duplicates(subset=['study_id']).sort_values(by='study_datetime') |
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return dict(zip(mimic_cxr['study_id'], mimic_cxr['study_datetime'])) |
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def load_ed_module(self, hadm_id=None, stay_id=None, reference_time=None): |
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if not self.start_time and stay_id is not None: |
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edstay = self.connect.sql( |
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f""" |
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SELECT intime, outtime |
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FROM edstays |
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WHERE stay_id = {stay_id} |
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""" |
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).df() |
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self.start_time = edstay['intime'].item() |
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self.end_time = edstay['outtime'].item() |
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self.load_module(self.ed_module_tables, hadm_id=hadm_id, stay_id=stay_id, reference_time=reference_time) |
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def load_mimic_cxr(self, study_id, reference_time=None): |
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self.load_module(self.mimic_cxr_tables, study_id=study_id, reference_time=reference_time) |
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if self.streamlit_flag: |
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self.report_path = mimic_cxr_text_path(self.reports_dir, self.subject_id, study_id, 'txt') |
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def load_module(self, module_dict, hadm_id=None, stay_id=None, study_id=None, reference_time=None): |
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for k, v in module_dict.items(): |
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if self.streamlit_flag or v.load: |
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query = f"FROM {k}" |
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conditions = [] |
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if hasattr(self, 'subject_id') and v.subject_id_filter: |
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conditions.append(f"subject_id={self.subject_id}") |
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if v.hadm_id_filter: |
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assert hadm_id is not None |
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conditions.append(f"hadm_id={hadm_id}") |
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if v.stay_id_filter: |
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assert stay_id is not None |
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conditions.append(f"stay_id={stay_id}") |
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if v.study_id_filter: |
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assert study_id is not None |
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conditions.append(f"study_id={study_id}") |
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if v.mimic_cxr_sectioned: |
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assert study_id is not None |
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conditions.append(f"study='s{study_id}'") |
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ands = ['AND'] * (len(conditions) * 2 - 1) |
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ands[0::2] = conditions |
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if conditions: |
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query += " WHERE (" |
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query += ' '.join(ands) |
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query += ")" |
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df = self.connect.sql(query).df() |
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if v.load: |
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columns = [v.groupby] + v.time_columns + v.index_columns + v.text_columns + v.value_columns + v.target_sections |
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if v.use_start_time: |
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df['start_time'] = self.start_time |
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columns += ['start_time'] |
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if reference_time is not None: |
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time_column = v.time_columns[-1] if not v.use_start_time else 'start_time' |
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df = df[df[time_column] < reference_time] |
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if self.streamlit_flag: |
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setattr(self, k, df) |
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if v.load: |
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columns = list(dict.fromkeys(columns)) |
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df = df.drop(columns=df.columns.difference(columns), axis=1) |
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setattr(self, f'{k}_feats', df) |
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def return_ed_module_features(self, stay_id, reference_time=None): |
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example_dict = {} |
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if stay_id is not None: |
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self.load_ed_module(stay_id=stay_id, reference_time=reference_time) |
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for k, v in self.ed_module_tables.items(): |
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if v.load: |
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df = getattr(self, f'{k}_feats') |
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if self.debug: |
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example_dict.setdefault('ed_tables', []).append(k) |
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if not df.empty: |
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assert f'{k}_index_value_feats' not in example_dict |
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time_column = v.time_columns[-1] if not v.use_start_time else 'start_time' |
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group_idx_to_y_idx, group_idx_to_datetime = OrderedDict(), OrderedDict() |
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groups = df.dropna(subset=v.index_columns + v.value_columns + v.text_columns, axis=0, how='all') |
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groups = groups.drop_duplicates(subset=[v.groupby])[list(dict.fromkeys([v.groupby, time_column]))] |
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groups = groups.reset_index(drop=True) |
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for i, row in groups.iterrows(): |
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group_idx_to_y_idx[row[v.groupby]] = i |
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group_idx_to_datetime[row[v.groupby]] = row[time_column] |
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if (v.index_columns or v.value_columns) and group_idx_to_y_idx: |
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example_dict[f'{k}_index_value_feats'] = torch.zeros(len(group_idx_to_y_idx), v.total_indices) |
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if v.index_columns: |
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example_dict[f'{k}_index_value_feats'] = df_to_tensor_index_columns( |
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df=df, |
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tensor=example_dict[f'{k}_index_value_feats'], |
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group_idx_to_y_idx=group_idx_to_y_idx, |
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groupby=v.groupby, |
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index_columns=v.index_columns, |
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) |
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if v.value_columns: |
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example_dict[f'{k}_index_value_feats'] = df_to_tensor_value_columns( |
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df=df, |
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tensor=example_dict[f'{k}_index_value_feats'], |
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group_idx_to_y_idx=group_idx_to_y_idx, |
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groupby=v.groupby, |
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value_columns=v.value_columns, |
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value_column_to_idx=v.value_column_to_idx |
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) |
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example_dict[f'{k}_index_value_token_type_ids'] = torch.full( |
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[example_dict[f'{k}_index_value_feats'].shape[0]], |
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self.token_type_to_token_type_id[k], |
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dtype=torch.long, |
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) |
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event_times = list(group_idx_to_datetime.values()) |
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assert all([i == i for i in event_times]) |
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time_delta = [self.compute_time_delta(i, reference_time) for i in event_times] |
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example_dict[f'{k}_index_value_time_delta'] = torch.tensor(time_delta)[:, None] |
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assert example_dict[f'{k}_index_value_feats'].shape[0] == example_dict[f'{k}_index_value_time_delta'].shape[0] |
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if v.text_columns: |
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for j in group_idx_to_y_idx.keys(): |
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group_text = df[df[v.groupby] == j] |
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for i in v.text_columns: |
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column_text = [format(k) for k in list(dict.fromkeys(group_text[i].tolist())) if k is not None] |
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if column_text: |
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example_dict.setdefault(f'{k}_{i}', []).append(f"{', '.join(column_text)}.") |
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event_times = group_text[time_column].iloc[0] |
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time_delta = self.compute_time_delta(event_times, reference_time, to_tensor=False) |
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example_dict.setdefault(f'{k}_{i}_time_delta', []).append(time_delta) |
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return example_dict |
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def return_mimic_cxr_features(self, study_id, reference_time=None): |
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example_dict = {} |
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if study_id is not None: |
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self.load_mimic_cxr(study_id=study_id, reference_time=reference_time) |
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for k, v in self.mimic_cxr_tables.items(): |
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if v.load: |
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df = getattr(self, f'{k}_feats') |
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if self.debug: |
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example_dict.setdefault('mimic_cxr_inputs', []).append(k) |
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if not df.empty: |
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group_idx_to_y_idx = OrderedDict() |
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groups = df.dropna( |
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subset=v.index_columns + v.value_columns + v.text_columns + v.target_sections, |
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axis=0, |
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how='all' |
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) |
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groups = groups.drop_duplicates(subset=[v.groupby])[[v.groupby]] |
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groups = groups.reset_index(drop=True) |
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for i, row in groups.iterrows(): |
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group_idx_to_y_idx[row[v.groupby]] = i |
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if v.index_columns and group_idx_to_y_idx: |
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example_dict[f'{k}_index_value_feats'] = torch.zeros(len(group_idx_to_y_idx), v.total_indices) |
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if v.index_columns: |
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example_dict[f'{k}_index_value_feats'] = df_to_tensor_index_columns( |
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df=df, |
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tensor=example_dict[f'{k}_index_value_feats'], |
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group_idx_to_y_idx=group_idx_to_y_idx, |
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groupby=v.groupby, |
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index_columns=v.index_columns, |
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) |
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example_dict[f'{k}_index_value_token_type_ids'] = torch.full( |
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[example_dict[f'{k}_index_value_feats'].shape[0]], |
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self.token_type_to_token_type_id[k], |
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dtype=torch.long, |
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) |
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if v.text_columns: |
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for j in group_idx_to_y_idx.keys(): |
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group_text = df[df[v.groupby] == j] |
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for i in v.text_columns: |
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column_text = [format(k) for k in list(dict.fromkeys(group_text[i].tolist())) if k is not None] |
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if column_text: |
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example_dict.setdefault(f'{i}', []).append(f"{', '.join(column_text)}.") |
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if v.target_sections: |
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for j in group_idx_to_y_idx.keys(): |
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group_text = df[df[v.groupby] == j] |
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for i in v.target_sections: |
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column_text = [format(k) for k in list(dict.fromkeys(group_text[i].tolist())) if k is not None] |
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assert len(column_text) == 1 |
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example_dict[i] = column_text[-1] |
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return example_dict |
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def compute_time_delta(self, event_time, reference_time, denominator = 3600, to_tensor=True): |
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""" |
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How to we transform time-delta inputs? It appears that minutes are used as the input to |
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a weight matrix in "Self-Supervised Transformer for Sparse and Irregularly Sampled Multivariate |
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Clinical Time-Series". This is almost confirmed by the CVE class defined here: |
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https://github.com/sindhura97/STraTS/blob/main/strats_notebook.ipynb, where the input has |
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a size of one. |
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""" |
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time_delta = reference_time - event_time |
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time_delta = time_delta.total_seconds() / (denominator) |
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assert isinstance(time_delta, float), f'time_delta should be float, not {type(time_delta)}.' |
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if time_delta < 0: |
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raise ValueError(f'time_delta should be greater than or equal to zero, not {time_delta}.') |
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time_delta = self.time_delta_map(time_delta) |
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if to_tensor: |
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time_delta = torch.tensor(time_delta) |
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return time_delta |
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def filter_admissions_by_time_span(self, df, time_column): |
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return df[(df[time_column] > self.start_time) & (df[time_column] <= self.end_time)] |
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