Geneformer / geneformer /tokenizer.py
Christina Theodoris
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"""
Geneformer tokenizer.
Input data:
Required format: raw counts scRNAseq data without feature selection as .loom file
Required row (gene) attribute: "ensembl_id"; Ensembl ID for each gene
Required col (cell) attribute: "n_counts"; total read counts in that cell
Optional col (cell) attribute: "filter_pass"; binary indicator of whether cell should be tokenized based on user-defined filtering criteria
Optional col (cell) attributes: any other cell metadata can be passed on to the tokenized dataset as a custom attribute dictionary as shown below
Usage:
from geneformer import TranscriptomeTokenizer
tk = TranscriptomeTokenizer({"cell_type": "cell_type", "organ_major": "organ_major"}, nproc=4)
tk.tokenize_data("loom_data_directory", "output_directory", "output_prefix")
"""
import pickle
from pathlib import Path
import logging
import warnings
warnings.filterwarnings("ignore", message=".*The 'nopython' keyword.*")
import loompy as lp
import numpy as np
from datasets import Dataset
logger = logging.getLogger(__name__)
GENE_MEDIAN_FILE = Path(__file__).parent / "gene_median_dictionary.pkl"
TOKEN_DICTIONARY_FILE = Path(__file__).parent / "token_dictionary.pkl"
def tokenize_cell(gene_vector, gene_tokens):
"""
Convert normalized gene expression vector to tokenized rank value encoding.
"""
# create array of gene vector with token indices
# mask undetected genes
nonzero_mask = np.nonzero(gene_vector)[0]
# sort by median-scaled gene values
sorted_indices = np.argsort(-gene_vector[nonzero_mask])
# tokenize
sentence_tokens = gene_tokens[nonzero_mask][sorted_indices]
return sentence_tokens
class TranscriptomeTokenizer:
def __init__(
self,
custom_attr_name_dict=None,
nproc=1,
gene_median_file=GENE_MEDIAN_FILE,
token_dictionary_file=TOKEN_DICTIONARY_FILE,
):
"""
Initialize tokenizer.
Parameters
----------
custom_attr_name_dict : None, dict
Dictionary of custom attributes to be added to the dataset.
Keys are the names of the attributes in the loom file.
Values are the names of the attributes in the dataset.
nproc : int
Number of processes to use for dataset mapping.
gene_median_file : Path
Path to pickle file containing dictionary of non-zero median
gene expression values across Genecorpus-30M.
token_dictionary_file : Path
Path to pickle file containing token dictionary (Ensembl IDs:token).
"""
# dictionary of custom attributes {output dataset column name: input .loom column name}
self.custom_attr_name_dict = custom_attr_name_dict
# number of processes for dataset mapping
self.nproc = nproc
# load dictionary of gene normalization factors
# (non-zero median value of expression across Genecorpus-30M)
with open(gene_median_file, "rb") as f:
self.gene_median_dict = pickle.load(f)
# load token dictionary (Ensembl IDs:token)
with open(token_dictionary_file, "rb") as f:
self.gene_token_dict = pickle.load(f)
# gene keys for full vocabulary
self.gene_keys = list(self.gene_median_dict.keys())
# protein-coding and miRNA gene list dictionary for selecting .loom rows for tokenization
self.genelist_dict = dict(zip(self.gene_keys, [True] * len(self.gene_keys)))
def tokenize_data(self, loom_data_directory, output_directory, output_prefix):
"""
Tokenize .loom files in loom_data_directory and save as tokenized .dataset in output_directory.
Parameters
----------
loom_data_directory : Path
Path to directory containing loom files
output_directory : Path
Path to directory where tokenized data will be saved as .dataset
output_prefix : str
Prefix for output .dataset
"""
tokenized_cells, cell_metadata = self.tokenize_files(Path(loom_data_directory))
tokenized_dataset = self.create_dataset(tokenized_cells, cell_metadata)
output_path = (Path(output_directory) / output_prefix).with_suffix(".dataset")
tokenized_dataset.save_to_disk(output_path)
def tokenize_files(self, loom_data_directory):
tokenized_cells = []
if self.custom_attr_name_dict is not None:
loom_cell_attr = [attr_key for attr_key in self.custom_attr_name_dict.keys()]
cell_metadata = {attr_key: [] for attr_key in self.custom_attr_name_dict.values()}
# loops through directories to tokenize .loom files
file_found = 0
for loom_file_path in loom_data_directory.glob("*.loom"):
file_found = 1
print(f"Tokenizing {loom_file_path}")
file_tokenized_cells, file_cell_metadata = self.tokenize_file(
loom_file_path
)
tokenized_cells += file_tokenized_cells
if self.custom_attr_name_dict is not None:
for k in loom_cell_attr:
cell_metadata[self.custom_attr_name_dict[k]] += file_cell_metadata[k]
else:
cell_metadata = None
if file_found == 0:
logger.error(
f"No .loom files found in directory {loom_data_directory}.")
raise
return tokenized_cells, cell_metadata
def tokenize_file(self, loom_file_path):
if self.custom_attr_name_dict is not None:
file_cell_metadata = {
attr_key: [] for attr_key in self.custom_attr_name_dict.keys()
}
with lp.connect(str(loom_file_path)) as data:
# define coordinates of detected protein-coding or miRNA genes and vector of their normalization factors
coding_miRNA_loc = np.where(
[self.genelist_dict.get(i, False) for i in data.ra["ensembl_id"]]
)[0]
norm_factor_vector = np.array(
[
self.gene_median_dict[i]
for i in data.ra["ensembl_id"][coding_miRNA_loc]
]
)
coding_miRNA_ids = data.ra["ensembl_id"][coding_miRNA_loc]
coding_miRNA_tokens = np.array(
[self.gene_token_dict[i] for i in coding_miRNA_ids]
)
# define coordinates of cells passing filters for inclusion (e.g. QC)
try:
data.ca["filter_pass"]
except AttributeError:
var_exists = False
else:
var_exists = True
if var_exists is True:
filter_pass_loc = np.where(
[True if i == 1 else False for i in data.ca["filter_pass"]]
)[0]
elif var_exists is False:
print(
f"{loom_file_path} has no column attribute 'filter_pass'; tokenizing all cells."
)
filter_pass_loc = np.array([i for i in range(data.shape[1])])
# scan through .loom files and tokenize cells
tokenized_cells = []
for (_ix, _selection, view) in data.scan(items=filter_pass_loc, axis=1):
# select subview with protein-coding and miRNA genes
subview = view.view[coding_miRNA_loc, :]
# normalize by total counts per cell and multiply by 10,000 to allocate bits to precision
# and normalize by gene normalization factors
subview_norm_array = (
subview[:, :]
/ subview.ca.n_counts
* 10_000
/ norm_factor_vector[:, None]
)
# tokenize subview gene vectors
tokenized_cells += [
tokenize_cell(subview_norm_array[:, i], coding_miRNA_tokens)
for i in range(subview_norm_array.shape[1])
]
# add custom attributes for subview to dict
if self.custom_attr_name_dict is not None:
for k in file_cell_metadata.keys():
file_cell_metadata[k] += subview.ca[k].tolist()
else:
file_cell_metadata = None
return tokenized_cells, file_cell_metadata
def create_dataset(self, tokenized_cells, cell_metadata):
# create dict for dataset creation
dataset_dict = {"input_ids": tokenized_cells}
if self.custom_attr_name_dict is not None:
dataset_dict.update(cell_metadata)
# create dataset
output_dataset = Dataset.from_dict(dataset_dict)
# truncate dataset
def truncate(example):
example["input_ids"] = example["input_ids"][0:2048]
return example
output_dataset_truncated = output_dataset.map(truncate, num_proc=self.nproc)
# measure lengths of dataset
def measure_length(example):
example["length"] = len(example["input_ids"])
return example
output_dataset_truncated_w_length = output_dataset_truncated.map(
measure_length, num_proc=self.nproc
)
return output_dataset_truncated_w_length