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	# Copyright (c) 2022, NVIDIA CORPORATION. All rights reserved.

	"""BERT Style dataset."""

	import numpy as np
	import torch

	from megatron import (
	get_args,
	get_tokenizer,
	mpu,
	print_rank_0
	)
	from megatron.data.dataset_utils import (
	get_samples_mapping,
	get_a_and_b_segments,
	truncate_segments,
	create_tokens_and_tokentypes,
	create_masked_lm_predictions
	)

	class BertDataset(torch.utils.data.Dataset):

	def __init__(self, name, indexed_dataset, data_prefix,
	num_epochs, max_num_samples, masked_lm_prob,
	max_seq_length, short_seq_prob, seed, binary_head):

	# Params to store.
	self.name = name
	self.seed = seed
	self.masked_lm_prob = masked_lm_prob
	self.max_seq_length = max_seq_length
	self.binary_head = binary_head

	# Dataset.
	self.indexed_dataset = indexed_dataset

	# Build the samples mapping.
	self.samples_mapping = get_samples_mapping(self.indexed_dataset,
	data_prefix,
	num_epochs,
	max_num_samples,
	self.max_seq_length - 3, # account for added tokens
	short_seq_prob,
	self.seed,
	self.name,
	self.binary_head)

	# Vocab stuff.
	tokenizer = get_tokenizer()
	self.vocab_id_list = list(tokenizer.inv_vocab.keys())
	self.vocab_id_to_token_dict = tokenizer.inv_vocab
	self.cls_id = tokenizer.cls
	self.sep_id = tokenizer.sep
	self.mask_id = tokenizer.mask
	self.pad_id = tokenizer.pad

	def __len__(self):
	return self.samples_mapping.shape[0]

	def __getitem__(self, idx):
	args = get_args()
	start_idx, end_idx, seq_length = self.samples_mapping[idx]
	sample = [self.indexed_dataset[i] for i in range(start_idx, end_idx)]
	# Note that this rng state should be numpy and not python since
	# python randint is inclusive whereas the numpy one is exclusive.
	# We % 232 since numpy requres the seed to be between 0 and 232 - 1
	np_rng = np.random.RandomState(seed=((self.seed + idx) % 2**32))
	train_sample = build_training_sample(sample, seq_length,
	self.max_seq_length, # needed for padding
	self.vocab_id_list,
	self.vocab_id_to_token_dict,
	self.cls_id, self.sep_id,
	self.mask_id, self.pad_id,
	self.masked_lm_prob, np_rng,
	self.binary_head)
	if args.return_data_index:
	train_sample['index'] = np.array([idx], dtype=np.int64)
	return train_sample




	def build_training_sample(sample,
	target_seq_length, max_seq_length,
	vocab_id_list, vocab_id_to_token_dict,
	cls_id, sep_id, mask_id, pad_id,
	masked_lm_prob, np_rng, binary_head):
	"""Biuld training sample.

	Arguments:
	sample: A list of sentences in which each sentence is a list token ids.
	target_seq_length: Desired sequence length.
	max_seq_length: Maximum length of the sequence. All values are padded to
	this length.
	vocab_id_list: List of vocabulary ids. Used to pick a random id.
	vocab_id_to_token_dict: A dictionary from vocab ids to text tokens.
	cls_id: Start of example id.
	sep_id: Separator id.
	mask_id: Mask token id.
	pad_id: Padding token id.
	masked_lm_prob: Probability to mask tokens.
	np_rng: Random number genenrator. Note that this rng state should be
	numpy and not python since python randint is inclusive for
	the opper bound whereas the numpy one is exclusive.
	"""

	if binary_head:
	# We assume that we have at least two sentences in the sample
	assert len(sample) > 1
	assert target_seq_length <= max_seq_length

	# Divide sample into two segments (A and B).
	if binary_head:
	tokens_a, tokens_b, is_next_random = get_a_and_b_segments(sample,
	np_rng)
	else:
	tokens_a = []
	for j in range(len(sample)):
	tokens_a.extend(sample[j])
	tokens_b = []
	is_next_random = False

	# Truncate to `target_sequence_length`.
	max_num_tokens = target_seq_length
	truncated = truncate_segments(tokens_a, tokens_b, len(tokens_a),
	len(tokens_b), max_num_tokens, np_rng)

	# Build tokens and toketypes.
	tokens, tokentypes = create_tokens_and_tokentypes(tokens_a, tokens_b,
	cls_id, sep_id)

	# Masking.
	max_predictions_per_seq = masked_lm_prob * max_num_tokens
	(tokens, masked_positions, masked_labels, _, _) = create_masked_lm_predictions(
	tokens, vocab_id_list, vocab_id_to_token_dict, masked_lm_prob,
	cls_id, sep_id, mask_id, max_predictions_per_seq, np_rng)

	# Padding.
	tokens_np, tokentypes_np, labels_np, padding_mask_np, loss_mask_np \
	= pad_and_convert_to_numpy(tokens, tokentypes, masked_positions,
	masked_labels, pad_id, max_seq_length)

	train_sample = {
	'text': tokens_np,
	'types': tokentypes_np,
	'labels': labels_np,
	'is_random': int(is_next_random),
	'loss_mask': loss_mask_np,
	'padding_mask': padding_mask_np,
	'truncated': int(truncated)}
	return train_sample


	def pad_and_convert_to_numpy(tokens, tokentypes, masked_positions,
	masked_labels, pad_id, max_seq_length):
	"""Pad sequences and convert them to numpy."""

	# Some checks.
	num_tokens = len(tokens)
	padding_length = max_seq_length - num_tokens
	assert padding_length >= 0, \
	f"num_tokens ({num_tokens}) is greater than " \
	"max_seq_length ({max_seq_length})."
	assert len(tokentypes) == num_tokens
	assert len(masked_positions) == len(masked_labels)

	# Tokens and token types.
	filler = [pad_id] * padding_length
	tokens_np = np.array(tokens + filler, dtype=np.int64)
	tokentypes_np = np.array(tokentypes + filler, dtype=np.int64)

	# Padding mask.
	padding_mask_np = np.array([1] * num_tokens + [0] * padding_length,
	dtype=np.int64)

	# Lables and loss mask.
	labels = [-1] * max_seq_length
	loss_mask = [0] * max_seq_length
	for i in range(len(masked_positions)):
	assert masked_positions[i] < num_tokens
	labels[masked_positions[i]] = masked_labels[i]
	loss_mask[masked_positions[i]] = 1
	labels_np = np.array(labels, dtype=np.int64)
	loss_mask_np = np.array(loss_mask, dtype=np.int64)

	return tokens_np, tokentypes_np, labels_np, padding_mask_np, loss_mask_np