|
""" |
|
Geneformer in silico perturber. |
|
|
|
Usage: |
|
from geneformer import InSilicoPerturber |
|
isp = InSilicoPerturber(perturb_type="delete", |
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perturb_rank_shift=None, |
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genes_to_perturb="all", |
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combos=0, |
|
anchor_gene=None, |
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model_type="Pretrained", |
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num_classes=0, |
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emb_mode="cell", |
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cell_emb_style="mean_pool", |
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filter_data={"cell_type":["cardiomyocyte"]}, |
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cell_states_to_model={"disease":(["dcm"],["ctrl"],["hcm"])}, |
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max_ncells=None, |
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emb_layer=-1, |
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forward_batch_size=100, |
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nproc=4, |
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save_raw_data=False) |
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isp.perturb_data("path/to/model", |
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"path/to/input_data", |
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"path/to/output_directory", |
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"output_prefix") |
|
""" |
|
|
|
|
|
import itertools as it |
|
import logging |
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import pickle |
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import seaborn as sns; sns.set() |
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import torch |
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from collections import defaultdict |
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from datasets import Dataset, load_from_disk |
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from tqdm.notebook import trange |
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from transformers import BertForMaskedLM, BertForTokenClassification, BertForSequenceClassification |
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|
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from .tokenizer import TOKEN_DICTIONARY_FILE |
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|
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logger = logging.getLogger(__name__) |
|
|
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def quant_layers(model): |
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layer_nums = [] |
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for name, parameter in model.named_parameters(): |
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if "layer" in name: |
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layer_nums += [name.split("layer.")[1].split(".")[0]] |
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return int(max(layer_nums))+1 |
|
|
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def flatten_list(megalist): |
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return [item for sublist in megalist for item in sublist] |
|
|
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def forward_pass_single_cell(model, example_cell, layer_to_quant): |
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example_cell.set_format(type="torch") |
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input_data = example_cell["input_ids"] |
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with torch.no_grad(): |
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outputs = model( |
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input_ids = input_data.to("cuda") |
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) |
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emb = torch.squeeze(outputs.hidden_states[layer_to_quant]) |
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del outputs |
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return emb |
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|
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def perturb_emb_by_index(emb, indices): |
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mask = torch.ones(emb.numel(), dtype=torch.bool) |
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mask[indices] = False |
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return emb[mask] |
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|
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def delete_index(example): |
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indexes = example["perturb_index"] |
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if len(indexes)>1: |
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indexes = flatten_list(indexes) |
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for index in sorted(indexes, reverse=True): |
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del example["input_ids"][index] |
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return example |
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|
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def overexpress_index(example): |
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indexes = example["perturb_index"] |
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if len(indexes)>1: |
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indexes = flatten_list(indexes) |
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for index in sorted(indexes, reverse=True): |
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example["input_ids"].insert(0, example["input_ids"].pop(index)) |
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return example |
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|
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def make_perturbation_batch(example_cell, |
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perturb_type, |
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tokens_to_perturb, |
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anchor_token, |
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combo_lvl, |
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num_proc): |
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if tokens_to_perturb == "all": |
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if perturb_type in ["overexpress","activate"]: |
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range_start = 1 |
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elif perturb_type in ["delete","inhibit"]: |
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range_start = 0 |
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indices_to_perturb = [[i] for i in range(range_start,example_cell["length"][0])] |
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elif combo_lvl>0 and (anchor_token is not None): |
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example_input_ids = example_cell["input_ids "][0] |
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anchor_index = example_input_ids.index(anchor_token[0]) |
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indices_to_perturb = [sorted([anchor_index,i]) if i!=anchor_index else None for i in range(example_cell["length"][0])] |
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indices_to_perturb = [item for item in indices_to_perturb if item is not None] |
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else: |
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example_input_ids = example_cell["input_ids"][0] |
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indices_to_perturb = [[example_input_ids.index(token)] if token in example_input_ids else None for token in tokens_to_perturb] |
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indices_to_perturb = [item for item in indices_to_perturb if item is not None] |
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|
|
|
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if combo_lvl>0 and (anchor_token is None): |
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if tokens_to_perturb != "all": |
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if len(tokens_to_perturb) == combo_lvl+1: |
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indices_to_perturb = [list(x) for x in it.combinations(indices_to_perturb, combo_lvl+1)] |
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else: |
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all_indices = [[i] for i in range(example_cell["length"][0])] |
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all_indices = [index for index in all_indices if index not in indices_to_perturb] |
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indices_to_perturb = [[[j for i in indices_to_perturb for j in i], x] for x in all_indices] |
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length = len(indices_to_perturb) |
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perturbation_dataset = Dataset.from_dict({"input_ids": example_cell["input_ids"]*length, "perturb_index": indices_to_perturb}) |
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if length<400: |
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num_proc_i = 1 |
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else: |
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num_proc_i = num_proc |
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if perturb_type == "delete": |
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perturbation_dataset = perturbation_dataset.map(delete_index, num_proc=num_proc_i) |
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elif perturb_type == "overexpress": |
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perturbation_dataset = perturbation_dataset.map(overexpress_index, num_proc=num_proc_i) |
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return perturbation_dataset, indices_to_perturb |
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|
|
|
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def make_comparison_batch(original_emb, indices_to_perturb): |
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all_embs_list = [] |
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for indices in indices_to_perturb: |
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emb_list = [] |
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start = 0 |
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if len(indices)>1 and isinstance(indices[0],list): |
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indices = flatten_list(indices) |
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for i in sorted(indices): |
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emb_list += [original_emb[start:i]] |
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start = i+1 |
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emb_list += [original_emb[start:]] |
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all_embs_list += [torch.cat(emb_list)] |
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return torch.stack(all_embs_list) |
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|
|
|
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def get_cell_state_avg_embs(model, |
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filtered_input_data, |
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cell_states_to_model, |
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layer_to_quant, |
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token_dictionary, |
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forward_batch_size, |
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num_proc): |
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possible_states = [value[0]+value[1]+value[2] for value in cell_states_to_model.values()][0] |
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state_embs_dict = dict() |
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for possible_state in possible_states: |
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state_embs_list = [] |
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|
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def filter_states(example): |
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return example[list(cell_states_to_model.keys())[0]] in [possible_state] |
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filtered_input_data_state = filtered_input_data.filter(filter_states, num_proc=num_proc) |
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total_batch_length = len(filtered_input_data_state) |
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if ((total_batch_length-1)/forward_batch_size).is_integer(): |
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forward_batch_size = forward_batch_size-1 |
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max_len = max(filtered_input_data_state["length"]) |
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for i in range(0, total_batch_length, forward_batch_size): |
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max_range = min(i+forward_batch_size, total_batch_length) |
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|
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state_minibatch = filtered_input_data_state.select([i for i in range(i, max_range)]) |
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state_minibatch.set_format(type="torch") |
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|
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input_data_minibatch = state_minibatch["input_ids"] |
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input_data_minibatch = pad_tensor_list(input_data_minibatch, max_len, token_dictionary) |
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|
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with torch.no_grad(): |
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outputs = model( |
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input_ids = input_data_minibatch.to("cuda") |
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) |
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|
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state_embs_i = outputs.hidden_states[layer_to_quant] |
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state_embs_list += [state_embs_i] |
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del outputs |
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del state_minibatch |
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del input_data_minibatch |
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del state_embs_i |
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torch.cuda.empty_cache() |
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state_embs_stack = torch.cat(state_embs_list) |
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avg_state_emb = torch.mean(state_embs_stack,dim=[0,1],keepdim=True) |
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state_embs_dict[possible_state] = avg_state_emb |
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return state_embs_dict |
|
|
|
|
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def quant_cos_sims(model, |
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perturbation_batch, |
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forward_batch_size, |
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layer_to_quant, |
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original_emb, |
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indices_to_perturb, |
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cell_states_to_model, |
|
state_embs_dict): |
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cos = torch.nn.CosineSimilarity(dim=2) |
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total_batch_length = len(perturbation_batch) |
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if ((total_batch_length-1)/forward_batch_size).is_integer(): |
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forward_batch_size = forward_batch_size-1 |
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if cell_states_to_model is None: |
|
comparison_batch = make_comparison_batch(original_emb, indices_to_perturb) |
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cos_sims = [] |
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else: |
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possible_states = [value[0]+value[1]+value[2] for value in cell_states_to_model.values()][0] |
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cos_sims_vs_alt_dict = dict(zip(possible_states,[[] for i in range(len(possible_states))])) |
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for i in range(0, total_batch_length, forward_batch_size): |
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max_range = min(i+forward_batch_size, total_batch_length) |
|
|
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perturbation_minibatch = perturbation_batch.select([i for i in range(i, max_range)]) |
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perturbation_minibatch.set_format(type="torch") |
|
|
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input_data_minibatch = perturbation_minibatch["input_ids"] |
|
|
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with torch.no_grad(): |
|
outputs = model( |
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input_ids = input_data_minibatch.to("cuda") |
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) |
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del input_data_minibatch |
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del perturbation_minibatch |
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|
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if len(indices_to_perturb)>1: |
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minibatch_emb = torch.squeeze(outputs.hidden_states[layer_to_quant]) |
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else: |
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minibatch_emb = outputs.hidden_states[layer_to_quant] |
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if cell_states_to_model is None: |
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minibatch_comparison = comparison_batch[i:max_range] |
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cos_sims += [cos(minibatch_emb, minibatch_comparison).to("cpu")] |
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else: |
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for state in possible_states: |
|
cos_sims_vs_alt_dict[state] += cos_sim_shift(original_emb, minibatch_emb, state_embs_dict[state]) |
|
del outputs |
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del minibatch_emb |
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if cell_states_to_model is None: |
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del minibatch_comparison |
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torch.cuda.empty_cache() |
|
if cell_states_to_model is None: |
|
cos_sims_stack = torch.cat(cos_sims) |
|
return cos_sims_stack |
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else: |
|
for state in possible_states: |
|
cos_sims_vs_alt_dict[state] = torch.cat(cos_sims_vs_alt_dict[state]) |
|
return cos_sims_vs_alt_dict |
|
|
|
|
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def cos_sim_shift(original_emb, minibatch_emb, alt_emb): |
|
cos = torch.nn.CosineSimilarity(dim=2) |
|
original_emb = torch.mean(original_emb,dim=0,keepdim=True)[None, :] |
|
alt_emb = alt_emb[None, None, :] |
|
origin_v_end = cos(original_emb,alt_emb) |
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perturb_v_end = cos(torch.mean(minibatch_emb,dim=1,keepdim=True),alt_emb) |
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return [(perturb_v_end-origin_v_end).to("cpu")] |
|
|
|
|
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def pad_tensor_list(tensor_list, dynamic_or_constant, token_dictionary): |
|
|
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pad_token_id = token_dictionary.get("<pad>") |
|
|
|
|
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if dynamic_or_constant == "dynamic": |
|
max_len = max([tensor.squeeze().numel() for tensor in tensor_list]) |
|
elif type(dynamic_or_constant) == int: |
|
max_len = dynamic_or_constant |
|
else: |
|
logger.warning( |
|
"If padding style is constant, must provide integer value. " \ |
|
"Setting padding to max input size 2048.") |
|
|
|
|
|
tensor_list = [torch.nn.functional.pad(tensor, pad=(0, |
|
max_len - tensor.numel()), |
|
mode='constant', |
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value=pad_token_id) for tensor in tensor_list] |
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|
|
|
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return torch.stack(tensor_list) |
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|
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class InSilicoPerturber: |
|
valid_option_dict = { |
|
"perturb_type": {"delete","overexpress","inhibit","activate"}, |
|
"perturb_rank_shift": {None, int}, |
|
"genes_to_perturb": {"all", list}, |
|
"combos": {0,1,2}, |
|
"anchor_gene": {None, str}, |
|
"model_type": {"Pretrained","GeneClassifier","CellClassifier"}, |
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"num_classes": {int}, |
|
"emb_mode": {"cell","cell_and_gene"}, |
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"cell_emb_style": {"mean_pool"}, |
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"filter_data": {None, dict}, |
|
"cell_states_to_model": {None, dict}, |
|
"max_ncells": {None, int}, |
|
"emb_layer": {-1, 0}, |
|
"forward_batch_size": {int}, |
|
"nproc": {int}, |
|
"save_raw_data": {False, True}, |
|
} |
|
def __init__( |
|
self, |
|
perturb_type="delete", |
|
perturb_rank_shift=None, |
|
genes_to_perturb="all", |
|
combos=0, |
|
anchor_gene=None, |
|
model_type="Pretrained", |
|
num_classes=0, |
|
emb_mode="cell", |
|
cell_emb_style="mean_pool", |
|
filter_data=None, |
|
cell_states_to_model=None, |
|
max_ncells=None, |
|
emb_layer=-1, |
|
forward_batch_size=100, |
|
nproc=4, |
|
save_raw_data=False, |
|
token_dictionary_file=TOKEN_DICTIONARY_FILE, |
|
): |
|
""" |
|
Initialize in silico perturber. |
|
|
|
Parameters |
|
---------- |
|
perturb_type : {"delete","overexpress","inhibit","activate"} |
|
Type of perturbation. |
|
"delete": delete gene from rank value encoding |
|
"overexpress": move gene to front of rank value encoding |
|
"inhibit": move gene to lower quartile of rank value encoding |
|
"activate": move gene to higher quartile of rank value encoding |
|
perturb_rank_shift : None, int |
|
Number of quartiles by which to shift rank of gene. |
|
For example, if perturb_type="activate" and perturb_rank_shift=1: |
|
genes in 4th quartile will move to middle of 3rd quartile. |
|
genes in 3rd quartile will move to middle of 2nd quartile. |
|
genes in 2nd quartile will move to middle of 1st quartile. |
|
genes in 1st quartile will move to front of rank value encoding. |
|
For example, if perturb_type="inhibit" and perturb_rank_shift=2: |
|
genes in 1st quartile will move to middle of 3rd quartile. |
|
genes in 2nd quartile will move to middle of 4th quartile. |
|
genes in 3rd or 4th quartile will move to bottom of rank value encoding. |
|
genes_to_perturb : "all", list |
|
Default is perturbing each gene detected in each cell in the dataset. |
|
Otherwise, may provide a list of ENSEMBL IDs of genes to perturb. |
|
combos : {0,1,2} |
|
Whether to perturb genes individually (0), in pairs (1), or in triplets (2). |
|
anchor_gene : None, str |
|
ENSEMBL ID of gene to use as anchor in combination perturbations. |
|
For example, if combos=1 and anchor_gene="ENSG00000148400": |
|
anchor gene will be perturbed in combination with each other gene. |
|
model_type : {"Pretrained","GeneClassifier","CellClassifier"} |
|
Whether model is the pretrained Geneformer or a fine-tuned gene or cell classifier. |
|
num_classes : int |
|
If model is a gene or cell classifier, specify number of classes it was trained to classify. |
|
For the pretrained Geneformer model, number of classes is 0 as it is not a classifier. |
|
emb_mode : {"cell","cell_and_gene"} |
|
Whether to output impact of perturbation on cell and/or gene embeddings. |
|
cell_emb_style : "mean_pool" |
|
Method for summarizing cell embeddings. |
|
Currently only option is mean pooling of gene embeddings for given cell. |
|
filter_data : None, dict |
|
Default is to use all input data for in silico perturbation study. |
|
Otherwise, dictionary specifying .dataset column name and list of values to filter by. |
|
cell_states_to_model: None, dict |
|
Cell states to model if testing perturbations that achieve goal state change. |
|
Single-item dictionary with key being cell attribute (e.g. "disease"). |
|
Value is tuple of three lists indicating start state, goal end state, and alternate possible end states. |
|
max_ncells : None, int |
|
Maximum number of cells to test. |
|
If None, will test all cells. |
|
emb_layer : {-1, 0} |
|
Embedding layer to use for quantification. |
|
-1: 2nd to last layer (recommended for pretrained Geneformer) |
|
0: last layer (recommended for cell classifier fine-tuned for disease state) |
|
forward_batch_size : int |
|
Batch size for forward pass. |
|
nproc : int |
|
Number of CPU processes to use. |
|
save_raw_data: {False,True} |
|
Whether to save raw perturbation data for each gene/cell. |
|
token_dictionary_file : Path |
|
Path to pickle file containing token dictionary (Ensembl ID:token). |
|
""" |
|
|
|
self.perturb_type = perturb_type |
|
self.perturb_rank_shift = perturb_rank_shift |
|
self.genes_to_perturb = genes_to_perturb |
|
self.combos = combos |
|
self.anchor_gene = anchor_gene |
|
self.model_type = model_type |
|
self.num_classes = num_classes |
|
self.emb_mode = emb_mode |
|
self.cell_emb_style = cell_emb_style |
|
self.filter_data = filter_data |
|
self.cell_states_to_model = cell_states_to_model |
|
self.max_ncells = max_ncells |
|
self.emb_layer = emb_layer |
|
self.forward_batch_size = forward_batch_size |
|
self.nproc = nproc |
|
self.save_raw_data = save_raw_data |
|
|
|
self.validate_options() |
|
|
|
|
|
with open(token_dictionary_file, "rb") as f: |
|
self.gene_token_dict = pickle.load(f) |
|
|
|
if anchor_gene is None: |
|
self.anchor_token = None |
|
else: |
|
self.anchor_token = self.gene_token_dict[self.anchor_gene] |
|
|
|
if genes_to_perturb == "all": |
|
self.tokens_to_perturb = "all" |
|
else: |
|
self.tokens_to_perturb = [self.gene_token_dict[gene] for gene in self.genes_to_perturb] |
|
|
|
def validate_options(self): |
|
for attr_name,valid_options in self.valid_option_dict.items(): |
|
attr_value = self.__dict__[attr_name] |
|
if type(attr_value) not in {list, dict}: |
|
if attr_value in valid_options: |
|
continue |
|
valid_type = False |
|
for option in valid_options: |
|
if (option in [int,list,dict]) and isinstance(attr_value, option): |
|
valid_type = True |
|
break |
|
if valid_type: |
|
continue |
|
logger.error( |
|
f"Invalid option for {attr_name}. " \ |
|
f"Valid options for {attr_name}: {valid_options}" |
|
) |
|
raise |
|
|
|
if self.perturb_type in ["delete","overexpress"]: |
|
if self.perturb_rank_shift is not None: |
|
if self.perturb_type == "delete": |
|
logger.warning( |
|
"perturb_rank_shift set to None. " \ |
|
"If perturb type is delete then gene is deleted entirely " \ |
|
"rather than shifted by quartile") |
|
elif self.perturb_type == "overexpress": |
|
logger.warning( |
|
"perturb_rank_shift set to None. " \ |
|
"If perturb type is activate then gene is moved to front " \ |
|
"of rank value encoding rather than shifted by quartile") |
|
self.perturb_rank_shift = None |
|
|
|
if (self.anchor_gene is not None) and (self.emb_mode == "cell_and_gene"): |
|
self.emb_mode = "cell" |
|
logger.warning( |
|
"emb_mode set to 'cell'. " \ |
|
"Currently, analysis with anchor gene " \ |
|
"only outputs effect on cell embeddings.") |
|
|
|
if self.cell_states_to_model is not None: |
|
if (len(self.cell_states_to_model.items()) == 1): |
|
for key,value in self.cell_states_to_model.items(): |
|
if (len(value) == 3) and isinstance(value, tuple): |
|
if isinstance(value[0],list) and isinstance(value[1],list) and isinstance(value[2],list): |
|
if len(value[0]) == 1 and len(value[1]) == 1: |
|
all_values = value[0]+value[1]+value[2] |
|
if len(all_values) == len(set(all_values)): |
|
continue |
|
else: |
|
logger.error( |
|
"Cell states to model must be a single-item dictionary with " \ |
|
"key being cell attribute (e.g. 'disease') and value being " \ |
|
"tuple of three lists indicating start state, goal end state, and alternate possible end states. " \ |
|
"Values should all be unique. " \ |
|
"For example: {'disease':(['dcm'],['ctrl'],['hcm'])}") |
|
raise |
|
if self.anchor_gene is not None: |
|
self.anchor_gene = None |
|
logger.warning( |
|
"anchor_gene set to None. " \ |
|
"Currently, anchor gene not available " \ |
|
"when modeling multiple cell states.") |
|
|
|
if self.perturb_type in ["inhibit","activate"]: |
|
if self.perturb_rank_shift is None: |
|
logger.error( |
|
"If perturb type is inhibit or activate then " \ |
|
"quartile to shift by must be specified.") |
|
raise |
|
|
|
if self.filter_data is not None: |
|
for key,value in self.filter_data.items(): |
|
if type(value) != list: |
|
self.filter_data[key] = [value] |
|
logger.warning( |
|
"Values in filter_data dict must be lists. " \ |
|
f"Changing {key} value to list ([{value}]).") |
|
|
|
def perturb_data(self, |
|
model_directory, |
|
input_data_file, |
|
output_directory, |
|
output_prefix): |
|
""" |
|
Perturb genes in input data and save as results in output_directory. |
|
|
|
Parameters |
|
---------- |
|
model_directory : Path |
|
Path to directory containing model |
|
input_data_file : Path |
|
Path to directory containing .dataset inputs |
|
output_directory : Path |
|
Path to directory where perturbation data will be saved as .csv |
|
output_prefix : str |
|
Prefix for output .dataset |
|
""" |
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filtered_input_data = self.load_and_filter(input_data_file) |
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model = self.load_model(model_directory) |
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layer_to_quant = quant_layers(model)+self.emb_layer |
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if self.cell_states_to_model is None: |
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state_embs_dict = None |
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else: |
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state_embs_dict = get_cell_state_avg_embs(model, |
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filtered_input_data, |
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self.cell_states_to_model, |
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layer_to_quant, |
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self.gene_token_dict, |
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self.forward_batch_size, |
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self.nproc) |
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self.in_silico_perturb(model, |
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filtered_input_data, |
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layer_to_quant, |
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state_embs_dict, |
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output_directory, |
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output_prefix) |
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def load_and_filter(self, input_data_file): |
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data = load_from_disk(input_data_file) |
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if self.filter_data is not None: |
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for key,value in self.filter_data.items(): |
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def filter_data_by_criteria(example): |
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return example[key] in value |
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data = data.filter(filter_data_by_criteria, num_proc=self.nproc) |
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if len(data) == 0: |
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logger.error( |
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"No cells remain after filtering. Check filtering criteria.") |
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raise |
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data_shuffled = data.shuffle(seed=42) |
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num_cells = len(data_shuffled) |
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if self.max_ncells != None: |
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num_cells = min(self.max_ncells,num_cells) |
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data_subset = data_shuffled.select([i for i in range(num_cells)]) |
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data_sorted = data_subset.sort("length",reverse=True) |
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return data_sorted |
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def load_model(self, model_directory): |
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if self.model_type == "Pretrained": |
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model = BertForMaskedLM.from_pretrained(model_directory, |
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output_hidden_states=True, |
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output_attentions=False) |
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elif self.model_type == "GeneClassifier": |
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model = BertForTokenClassification.from_pretrained(model_directory, |
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num_labels=self.num_classes, |
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output_hidden_states=True, |
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output_attentions=False) |
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elif self.model_type == "CellClassifier": |
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model = BertForSequenceClassification.from_pretrained(model_directory, |
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num_labels=self.num_classes, |
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output_hidden_states=True, |
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output_attentions=False) |
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model.eval() |
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model = model.to("cuda:0") |
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return model |
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def in_silico_perturb(self, |
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model, |
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filtered_input_data, |
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layer_to_quant, |
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state_embs_dict, |
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output_directory, |
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output_prefix): |
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output_path_prefix = f"{output_directory}in_silico_{self.perturb_type}_{output_prefix}_dict_1Kbatch" |
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if self.anchor_token is not None: |
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def if_has_tokens_to_perturb(example): |
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return (len(set(example["input_ids"]).intersection(self.anchor_token))==len(self.anchor_token)) |
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filtered_input_data = filtered_input_data.filter(if_has_tokens_to_perturb, num_proc=self.nproc) |
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logger.info(f"# cells with anchor gene: {len(filtered_input_data)}") |
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if self.tokens_to_perturb != "all": |
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def if_has_tokens_to_perturb(example): |
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return (len(set(example["input_ids"]).intersection(self.tokens_to_perturb))>self.combos) |
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filtered_input_data = filtered_input_data.filter(if_has_tokens_to_perturb, num_proc=self.nproc) |
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cos_sims_dict = defaultdict(list) |
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pickle_batch = -1 |
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for i in trange(len(filtered_input_data)): |
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example_cell = filtered_input_data.select([i]) |
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original_emb = forward_pass_single_cell(model, example_cell, layer_to_quant) |
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gene_list = torch.squeeze(example_cell["input_ids"]) |
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example_cell = filtered_input_data.select([i]) |
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if self.anchor_token is None: |
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for combo_lvl in range(self.combos+1): |
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perturbation_batch, indices_to_perturb = make_perturbation_batch(example_cell, |
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self.perturb_type, |
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self.tokens_to_perturb, |
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self.anchor_token, |
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combo_lvl, |
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self.nproc) |
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cos_sims_data = quant_cos_sims(model, |
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perturbation_batch, |
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self.forward_batch_size, |
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layer_to_quant, |
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original_emb, |
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indices_to_perturb, |
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self.cell_states_to_model, |
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state_embs_dict) |
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if self.cell_states_to_model is None: |
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cos_sims_data = cos_sims_data.to("cuda") |
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for j in range(cos_sims_data.shape[0]): |
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if self.genes_to_perturb != "all": |
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j_index = torch.tensor(indices_to_perturb[j]) |
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if j_index.shape[0]>1: |
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j_index = torch.squeeze(j_index) |
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else: |
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j_index = torch.tensor([j]) |
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perturbed_gene = torch.index_select(gene_list, 0, j_index) |
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if perturbed_gene.shape[0]==1: |
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perturbed_gene = perturbed_gene.item() |
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elif perturbed_gene.shape[0]>1: |
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perturbed_gene = tuple(perturbed_gene.tolist()) |
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cell_cos_sim = torch.mean(cos_sims_data[j]).item() |
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cos_sims_dict[(perturbed_gene, "cell_emb")] += [cell_cos_sim] |
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if self.emb_mode == "cell_and_gene": |
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for k in range(cos_sims_data.shape[1]): |
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cos_sim_value = cos_sims_data[j][k] |
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affected_gene = gene_list[k].item() |
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cos_sims_dict[(perturbed_gene, affected_gene)] += [cos_sim_value.item()] |
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else: |
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origin_state_key = [value[0] for value in self.cell_states_to_model.values()][0][0] |
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cos_sims_origin = cos_sims_data[origin_state_key] |
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for j in range(cos_sims_origin.shape[0]): |
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if (self.genes_to_perturb != "all") or (combo_lvl>0): |
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j_index = torch.tensor(indices_to_perturb[j]) |
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if j_index.shape[0]>1: |
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j_index = torch.squeeze(j_index) |
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else: |
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j_index = torch.tensor([j]) |
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perturbed_gene = torch.index_select(gene_list, 0, j_index) |
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if perturbed_gene.shape[0]==1: |
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perturbed_gene = perturbed_gene.item() |
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elif perturbed_gene.shape[0]>1: |
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perturbed_gene = tuple(perturbed_gene.tolist()) |
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data_list = [] |
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for data in list(cos_sims_data.values()): |
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data_item = data.to("cuda") |
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cell_data = torch.mean(data_item[j]).item() |
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data_list += [cell_data] |
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cos_sims_dict[(perturbed_gene, "cell_emb")] += [tuple(data_list)] |
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elif self.anchor_token is not None: |
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perturbation_batch, indices_to_perturb = make_perturbation_batch(example_cell, |
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self.perturb_type, |
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self.tokens_to_perturb, |
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None, |
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0, |
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self.nproc) |
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cos_sims_data = quant_cos_sims(model, |
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perturbation_batch, |
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self.forward_batch_size, |
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layer_to_quant, |
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original_emb, |
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indices_to_perturb, |
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self.cell_states_to_model, |
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state_embs_dict) |
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cos_sims_data = cos_sims_data.to("cuda") |
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combo_perturbation_batch, combo_indices_to_perturb = make_perturbation_batch(example_cell, |
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self.perturb_type, |
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self.tokens_to_perturb, |
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self.anchor_token, |
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1, |
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self.nproc) |
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combo_cos_sims_data = quant_cos_sims(model, |
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combo_perturbation_batch, |
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self.forward_batch_size, |
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layer_to_quant, |
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original_emb, |
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combo_indices_to_perturb, |
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self.cell_states_to_model, |
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state_embs_dict) |
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combo_cos_sims_data = combo_cos_sims_data.to("cuda") |
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anchor_index = example_cell["input_ids"][0].index(self.anchor_token[0]) |
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anchor_cell_cos_sim = torch.mean(cos_sims_data[anchor_index]).item() |
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non_anchor_indices = [k for k in range(cos_sims_data.shape[0]) if k != anchor_index] |
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cos_sims_data = cos_sims_data[non_anchor_indices,:] |
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for j in range(cos_sims_data.shape[0]): |
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|
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if j<anchor_index: |
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j_index = torch.tensor([j]) |
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else: |
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j_index = torch.tensor([j+1]) |
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perturbed_gene = torch.index_select(gene_list, 0, j_index) |
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perturbed_gene = perturbed_gene.item() |
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cell_cos_sim = torch.mean(cos_sims_data[j]).item() |
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combo_cos_sim = torch.mean(combo_cos_sims_data[j]).item() |
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cos_sims_dict[(perturbed_gene, "cell_emb")] += [(anchor_cell_cos_sim, |
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cell_cos_sim, |
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combo_cos_sim)] |
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if (i/100).is_integer(): |
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with open(f"{output_path_prefix}{pickle_batch}_raw.pickle", "wb") as fp: |
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pickle.dump(cos_sims_dict, fp) |
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|
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if (i/1000).is_integer(): |
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pickle_batch = pickle_batch+1 |
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|
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del perturbed_gene |
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del cos_sims_data |
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if self.cell_states_to_model is None: |
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del cell_cos_sim |
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if self.cell_states_to_model is not None: |
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del cell_data |
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del data_list |
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elif self.anchor_token is None: |
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del affected_gene |
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del cos_sim_value |
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else: |
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del combo_cos_sim |
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del combo_cos_sims_data |
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|
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del cos_sims_dict |
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cos_sims_dict = defaultdict(list) |
|
torch.cuda.empty_cache() |
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|
|
with open(f"{output_path_prefix}{pickle_batch}_raw.pickle", "wb") as fp: |
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pickle.dump(cos_sims_dict, fp) |
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