relik-reader-deberta-v3-base-aida / modeling_relik.py

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	from typing import Any, Dict, Optional

	import torch
	from transformers import AutoModel, PreTrainedModel
	from transformers.activations import ClippedGELUActivation, GELUActivation
	from transformers.configuration_utils import PretrainedConfig
	from transformers.modeling_utils import PoolerEndLogits

	from .configuration_relik import RelikReaderConfig


	class RelikReaderSample:
	def __init__(self, **kwargs):
	super().__setattr__("_d", {})
	self._d = kwargs

	def __getattribute__(self, item):
	return super(RelikReaderSample, self).__getattribute__(item)

	def __getattr__(self, item):
	if item.startswith("__") and item.endswith("__"):
	# this is likely some python library-specific variable (such as __deepcopy__ for copy)
	# better follow standard behavior here
	raise AttributeError(item)
	elif item in self._d:
	return self._d[item]
	else:
	return None

	def __setattr__(self, key, value):
	if key in self._d:
	self._d[key] = value
	else:
	super().__setattr__(key, value)
	self._d[key] = value


	activation2functions = {
	"relu": torch.nn.ReLU(),
	"gelu": GELUActivation(),
	"gelu_10": ClippedGELUActivation(-10, 10),
	}


	class PoolerEndLogitsBi(PoolerEndLogits):
	def __init__(self, config: PretrainedConfig):
	super().__init__(config)
	self.dense_1 = torch.nn.Linear(config.hidden_size, 2)

	def forward(
	self,
	hidden_states: torch.FloatTensor,
	start_states: Optional[torch.FloatTensor] = None,
	start_positions: Optional[torch.LongTensor] = None,
	p_mask: Optional[torch.FloatTensor] = None,
	) -> torch.FloatTensor:
	if p_mask is not None:
	p_mask = p_mask.unsqueeze(-1)
	logits = super().forward(
	hidden_states,
	start_states,
	start_positions,
	p_mask,
	)
	return logits


	class RelikReaderSpanModel(PreTrainedModel):
	config_class = RelikReaderConfig

	def __init__(self, config: RelikReaderConfig, args, *kwargs):
	super().__init__(config)
	# Transformer model declaration
	self.config = config
	self.transformer_model = (
	AutoModel.from_pretrained(self.config.transformer_model)
	if self.config.num_layers is None
	else AutoModel.from_pretrained(
	self.config.transformer_model, num_hidden_layers=self.config.num_layers
	)
	)
	self.transformer_model.resize_token_embeddings(
	self.transformer_model.config.vocab_size
	+ self.config.additional_special_symbols
	)

	self.activation = self.config.activation
	self.linears_hidden_size = self.config.linears_hidden_size
	self.use_last_k_layers = self.config.use_last_k_layers

	# named entity detection layers
	self.ned_start_classifier = self._get_projection_layer(
	self.activation, last_hidden=2, layer_norm=False
	)
	self.ned_end_classifier = PoolerEndLogits(self.transformer_model.config)

	# END entity disambiguation layer
	self.ed_start_projector = self._get_projection_layer(self.activation)
	self.ed_end_projector = self._get_projection_layer(self.activation)

	self.training = self.config.training

	# criterion
	self.criterion = torch.nn.CrossEntropyLoss()

	def _get_projection_layer(
	self,
	activation: str,
	last_hidden: Optional[int] = None,
	input_hidden=None,
	layer_norm: bool = True,
	) -> torch.nn.Sequential:
	head_components = [
	torch.nn.Dropout(0.1),
	torch.nn.Linear(
	(
	self.transformer_model.config.hidden_size * self.use_last_k_layers
	if input_hidden is None
	else input_hidden
	),
	self.linears_hidden_size,
	),
	activation2functions[activation],
	torch.nn.Dropout(0.1),
	torch.nn.Linear(
	self.linears_hidden_size,
	self.linears_hidden_size if last_hidden is None else last_hidden,
	),
	]

	if layer_norm:
	head_components.append(
	torch.nn.LayerNorm(
	self.linears_hidden_size if last_hidden is None else last_hidden,
	self.transformer_model.config.layer_norm_eps,
	)
	)

	return torch.nn.Sequential(*head_components)

	def _mask_logits(self, logits: torch.Tensor, mask: torch.Tensor) -> torch.Tensor:
	mask = mask.unsqueeze(-1)
	if next(self.parameters()).dtype == torch.float16:
	logits = logits * (1 - mask) - 65500 * mask
	else:
	logits = logits * (1 - mask) - 1e30 * mask
	return logits

	def _get_model_features(
	self,
	input_ids: torch.Tensor,
	attention_mask: torch.Tensor,
	token_type_ids: Optional[torch.Tensor],
	):
	model_input = {
	"input_ids": input_ids,
	"attention_mask": attention_mask,
	"output_hidden_states": self.use_last_k_layers > 1,
	}

	if token_type_ids is not None:
	model_input["token_type_ids"] = token_type_ids

	model_output = self.transformer_model(**model_input)

	if self.use_last_k_layers > 1:
	model_features = torch.cat(
	model_output[1][-self.use_last_k_layers :], dim=-1
	)
	else:
	model_features = model_output[0]

	return model_features

	def compute_ned_end_logits(
	self,
	start_predictions,
	start_labels,
	model_features,
	prediction_mask,
	batch_size,
	) -> Optional[torch.Tensor]:
	# todo: maybe when constraining on the spans,
	# we should not use a prediction_mask for the end tokens.
	# at least we should not during training imo
	start_positions = start_labels if self.training else start_predictions
	start_positions_indices = (
	torch.arange(start_positions.size(1), device=start_positions.device)
	.unsqueeze(0)
	.expand(batch_size, -1)[start_positions > 0]
	).to(start_positions.device)

	if len(start_positions_indices) > 0:
	expanded_features = model_features.repeat_interleave(
	torch.sum(start_positions > 0, dim=-1), dim=0
	)
	expanded_prediction_mask = prediction_mask.repeat_interleave(
	torch.sum(start_positions > 0, dim=-1), dim=0
	)
	end_logits = self.ned_end_classifier(
	hidden_states=expanded_features,
	start_positions=start_positions_indices,
	p_mask=expanded_prediction_mask,
	)

	return end_logits

	return None

	def compute_classification_logits(
	self,
	model_features,
	special_symbols_mask,
	prediction_mask,
	batch_size,
	start_positions=None,
	end_positions=None,
	) -> torch.Tensor:
	if start_positions is None or end_positions is None:
	start_positions = torch.zeros_like(prediction_mask)
	end_positions = torch.zeros_like(prediction_mask)

	model_start_features = self.ed_start_projector(model_features)
	model_end_features = self.ed_end_projector(model_features)
	model_end_features[start_positions > 0] = model_end_features[end_positions > 0]

	model_ed_features = torch.cat(
	[model_start_features, model_end_features], dim=-1
	)

	# computing ed features
	classes_representations = torch.sum(special_symbols_mask, dim=1)[0].item()
	special_symbols_representation = model_ed_features[special_symbols_mask].view(
	batch_size, classes_representations, -1
	)

	logits = torch.bmm(
	model_ed_features,
	torch.permute(special_symbols_representation, (0, 2, 1)),
	)

	logits = self._mask_logits(logits, prediction_mask)

	return logits

	def forward(
	self,
	input_ids: torch.Tensor,
	attention_mask: torch.Tensor,
	token_type_ids: Optional[torch.Tensor] = None,
	prediction_mask: Optional[torch.Tensor] = None,
	special_symbols_mask: Optional[torch.Tensor] = None,
	start_labels: Optional[torch.Tensor] = None,
	end_labels: Optional[torch.Tensor] = None,
	use_predefined_spans: bool = False,
	*args,
	**kwargs,
	) -> Dict[str, Any]:
	batch_size, seq_len = input_ids.shape

	model_features = self._get_model_features(
	input_ids, attention_mask, token_type_ids
	)

	ned_start_labels = None

	# named entity detection if required
	if use_predefined_spans: # no need to compute spans
	ned_start_logits, ned_start_probabilities, ned_start_predictions = (
	None,
	None,
	(
	torch.clone(start_labels)
	if start_labels is not None
	else torch.zeros_like(input_ids)
	),
	)
	ned_end_logits, ned_end_probabilities, ned_end_predictions = (
	None,
	None,
	(
	torch.clone(end_labels)
	if end_labels is not None
	else torch.zeros_like(input_ids)
	),
	)

	ned_start_predictions[ned_start_predictions > 0] = 1
	ned_end_predictions[ned_end_predictions > 0] = 1

	else: # compute spans
	# start boundary prediction
	ned_start_logits = self.ned_start_classifier(model_features)
	ned_start_logits = self._mask_logits(ned_start_logits, prediction_mask)
	ned_start_probabilities = torch.softmax(ned_start_logits, dim=-1)
	ned_start_predictions = ned_start_probabilities.argmax(dim=-1)

	# end boundary prediction
	ned_start_labels = (
	torch.zeros_like(start_labels) if start_labels is not None else None
	)

	if ned_start_labels is not None:
	ned_start_labels[start_labels == -100] = -100
	ned_start_labels[start_labels > 0] = 1

	ned_end_logits = self.compute_ned_end_logits(
	ned_start_predictions,
	ned_start_labels,
	model_features,
	prediction_mask,
	batch_size,
	)

	if ned_end_logits is not None:
	ned_end_probabilities = torch.softmax(ned_end_logits, dim=-1)
	ned_end_predictions = torch.argmax(ned_end_probabilities, dim=-1)
	else:
	ned_end_logits, ned_end_probabilities = None, None
	ned_end_predictions = ned_start_predictions.new_zeros(batch_size)

	# flattening end predictions
	# (flattening can happen only if the
	# end boundaries were not predicted using the gold labels)
	if not self.training and ned_end_logits is not None:
	flattened_end_predictions = torch.zeros_like(ned_start_predictions)

	row_indices, start_positions = torch.where(ned_start_predictions > 0)
	ned_end_predictions[
	ned_end_predictions < start_positions
	] = start_positions[ned_end_predictions < start_positions]

	end_spans_repeated = (row_indices + 1) * seq_len + ned_end_predictions
	cummax_values, _ = end_spans_repeated.cummax(dim=0)

	end_spans_repeated = end_spans_repeated > torch.cat(
	(end_spans_repeated[:1], cummax_values[:-1])
	)
	end_spans_repeated[0] = True

	ned_start_predictions[
	row_indices[~end_spans_repeated],
	start_positions[~end_spans_repeated],
	] = 0

	row_indices, start_positions, ned_end_predictions = (
	row_indices[end_spans_repeated],
	start_positions[end_spans_repeated],
	ned_end_predictions[end_spans_repeated],
	)

	flattened_end_predictions[row_indices, ned_end_predictions] = 1

	total_start_predictions, total_end_predictions = (
	ned_start_predictions.sum(),
	flattened_end_predictions.sum(),
	)

	assert (
	total_start_predictions == 0
	or total_start_predictions == total_end_predictions
	), (
	f"Total number of start predictions = {total_start_predictions}. "
	f"Total number of end predictions = {total_end_predictions}"
	)
	ned_end_predictions = flattened_end_predictions
	else:
	ned_end_predictions = torch.zeros_like(ned_start_predictions)

	start_position, end_position = (
	(start_labels, end_labels)
	if self.training
	else (ned_start_predictions, ned_end_predictions)
	)

	# Entity disambiguation
	ed_logits = self.compute_classification_logits(
	model_features,
	special_symbols_mask,
	prediction_mask,
	batch_size,
	start_position,
	end_position,
	)
	ed_probabilities = torch.softmax(ed_logits, dim=-1)
	ed_predictions = torch.argmax(ed_probabilities, dim=-1)

	# output build
	output_dict = dict(
	batch_size=batch_size,
	ned_start_logits=ned_start_logits,
	ned_start_probabilities=ned_start_probabilities,
	ned_start_predictions=ned_start_predictions,
	ned_end_logits=ned_end_logits,
	ned_end_probabilities=ned_end_probabilities,
	ned_end_predictions=ned_end_predictions,
	ed_logits=ed_logits,
	ed_probabilities=ed_probabilities,
	ed_predictions=ed_predictions,
	)

	# compute loss if labels
	if start_labels is not None and end_labels is not None and self.training:
	# named entity detection loss

	# start
	if ned_start_logits is not None:
	ned_start_loss = self.criterion(
	ned_start_logits.view(-1, ned_start_logits.shape[-1]),
	ned_start_labels.view(-1),
	)
	else:
	ned_start_loss = 0

	# end
	if ned_end_logits is not None:
	ned_end_labels = torch.zeros_like(end_labels)
	ned_end_labels[end_labels == -100] = -100
	ned_end_labels[end_labels > 0] = 1

	ned_end_loss = self.criterion(
	ned_end_logits,
	(
	torch.arange(
	ned_end_labels.size(1), device=ned_end_labels.device
	)
	.unsqueeze(0)
	.expand(batch_size, -1)[ned_end_labels > 0]
	).to(ned_end_labels.device),
	)

	else:
	ned_end_loss = 0

	# entity disambiguation loss
	start_labels[ned_start_labels != 1] = -100
	ed_labels = torch.clone(start_labels)
	ed_labels[end_labels > 0] = end_labels[end_labels > 0]
	ed_loss = self.criterion(
	ed_logits.view(-1, ed_logits.shape[-1]),
	ed_labels.view(-1),
	)

	output_dict["ned_start_loss"] = ned_start_loss
	output_dict["ned_end_loss"] = ned_end_loss
	output_dict["ed_loss"] = ed_loss

	output_dict["loss"] = ned_start_loss + ned_end_loss + ed_loss

	return output_dict


	class RelikReaderREModel(PreTrainedModel):
	config_class = RelikReaderConfig

	def __init__(self, config, args, *kwargs):
	super().__init__(config)
	# Transformer model declaration
	# self.transformer_model_name = transformer_model
	self.config = config
	self.transformer_model = (
	AutoModel.from_pretrained(config.transformer_model)
	if config.num_layers is None
	else AutoModel.from_pretrained(
	config.transformer_model, num_hidden_layers=config.num_layers
	)
	)
	self.transformer_model.resize_token_embeddings(
	self.transformer_model.config.vocab_size
	+ config.additional_special_symbols
	+ config.additional_special_symbols_types,
	)

	# named entity detection layers
	self.ned_start_classifier = self._get_projection_layer(
	config.activation, last_hidden=2, layer_norm=False
	)

	self.ned_end_classifier = PoolerEndLogitsBi(self.transformer_model.config)

	self.relation_disambiguation_loss = (
	config.relation_disambiguation_loss
	if hasattr(config, "relation_disambiguation_loss")
	else False
	)

	if self.config.entity_type_loss and self.config.add_entity_embedding:
	input_hidden_ents = 3 * self.config.linears_hidden_size
	else:
	input_hidden_ents = 2 * self.config.linears_hidden_size

	self.re_projector = self._get_projection_layer(
	config.activation,
	input_hidden=2 * self.transformer_model.config.hidden_size,
	hidden=input_hidden_ents,
	last_hidden=2 * self.config.linears_hidden_size,
	)

	self.re_relation_projector = self._get_projection_layer(
	config.activation,
	input_hidden=self.transformer_model.config.hidden_size,
	)

	if self.config.entity_type_loss or self.relation_disambiguation_loss:
	self.re_entities_projector = self._get_projection_layer(
	config.activation,
	input_hidden=2 * self.transformer_model.config.hidden_size,
	)
	self.re_definition_projector = self._get_projection_layer(
	config.activation,
	)

	self.re_classifier = self._get_projection_layer(
	config.activation,
	input_hidden=config.linears_hidden_size,
	last_hidden=2,
	layer_norm=False,
	)

	self.training = config.training

	# criterion
	self.criterion = torch.nn.CrossEntropyLoss()
	self.criterion_type = torch.nn.BCEWithLogitsLoss()

	def _get_projection_layer(
	self,
	activation: str,
	last_hidden: Optional[int] = None,
	hidden: Optional[int] = None,
	input_hidden=None,
	layer_norm: bool = True,
	) -> torch.nn.Sequential:
	head_components = [
	torch.nn.Dropout(0.1),
	torch.nn.Linear(
	(
	self.transformer_model.config.hidden_size
	* self.config.use_last_k_layers
	if input_hidden is None
	else input_hidden
	),
	self.config.linears_hidden_size if hidden is None else hidden,
	),
	activation2functions[activation],
	torch.nn.Dropout(0.1),
	torch.nn.Linear(
	self.config.linears_hidden_size if hidden is None else hidden,
	self.config.linears_hidden_size if last_hidden is None else last_hidden,
	),
	]

	if layer_norm:
	head_components.append(
	torch.nn.LayerNorm(
	(
	self.config.linears_hidden_size
	if last_hidden is None
	else last_hidden
	),
	self.transformer_model.config.layer_norm_eps,
	)
	)

	return torch.nn.Sequential(*head_components)

	def _mask_logits(self, logits: torch.Tensor, mask: torch.Tensor) -> torch.Tensor:
	mask = mask.unsqueeze(-1)
	if next(self.parameters()).dtype == torch.float16:
	logits = logits * (1 - mask) - 65500 * mask
	else:
	logits = logits * (1 - mask) - 1e30 * mask
	return logits

	def _get_model_features(
	self,
	input_ids: torch.Tensor,
	attention_mask: torch.Tensor,
	token_type_ids: Optional[torch.Tensor],
	):
	model_input = {
	"input_ids": input_ids,
	"attention_mask": attention_mask,
	"output_hidden_states": self.config.use_last_k_layers > 1,
	}

	if token_type_ids is not None:
	model_input["token_type_ids"] = token_type_ids

	model_output = self.transformer_model(**model_input)

	if self.config.use_last_k_layers > 1:
	model_features = torch.cat(
	model_output[1][-self.config.use_last_k_layers :], dim=-1
	)
	else:
	model_features = model_output[0]

	return model_features

	def compute_ned_end_logits(
	self,
	start_predictions,
	start_labels,
	model_features,
	prediction_mask,
	batch_size,
	mask_preceding: bool = False,
	) -> Optional[torch.Tensor]:
	# todo: maybe when constraining on the spans,
	# we should not use a prediction_mask for the end tokens.
	# at least we should not during training imo
	start_positions = start_labels if self.training else start_predictions
	start_positions_indices = (
	torch.arange(start_positions.size(1), device=start_positions.device)
	.unsqueeze(0)
	.expand(batch_size, -1)[start_positions > 0]
	).to(start_positions.device)

	if len(start_positions_indices) > 0:
	expanded_features = model_features.repeat_interleave(
	torch.sum(start_positions > 0, dim=-1), dim=0
	)
	expanded_prediction_mask = prediction_mask.repeat_interleave(
	torch.sum(start_positions > 0, dim=-1), dim=0
	)
	if mask_preceding:
	expanded_prediction_mask[
	torch.arange(
	expanded_prediction_mask.shape[1],
	device=expanded_prediction_mask.device,
	)
	< start_positions_indices.unsqueeze(1)
	] = 1
	end_logits = self.ned_end_classifier(
	hidden_states=expanded_features,
	start_positions=start_positions_indices,
	p_mask=expanded_prediction_mask,
	)

	return end_logits

	return None

	def compute_relation_logits(
	self,
	model_entity_features,
	special_symbols_features,
	) -> torch.Tensor:
	model_subject_object_features = self.re_projector(model_entity_features)
	model_subject_features = model_subject_object_features[
	:, :, : model_subject_object_features.shape[-1] // 2
	]
	model_object_features = model_subject_object_features[
	:, :, model_subject_object_features.shape[-1] // 2 :
	]
	special_symbols_start_representation = self.re_relation_projector(
	special_symbols_features
	)
	re_logits = torch.einsum(
	"bse,bde,bfe->bsdfe",
	model_subject_features,
	model_object_features,
	special_symbols_start_representation,
	)
	re_logits = self.re_classifier(re_logits)

	return re_logits

	def compute_entity_logits(
	self,
	model_entity_features,
	special_symbols_features,
	) -> torch.Tensor:
	model_ed_features = self.re_entities_projector(model_entity_features)
	special_symbols_ed_representation = self.re_definition_projector(
	special_symbols_features
	)

	logits = torch.bmm(
	model_ed_features,
	torch.permute(special_symbols_ed_representation, (0, 2, 1)),
	)
	logits = self._mask_logits(
	logits, (model_entity_features == -100).all(2).long()
	)
	return logits

	def compute_loss(self, logits, labels, mask=None):
	logits = logits.reshape(-1, logits.shape[-1])
	labels = labels.reshape(-1).long()
	if mask is not None:
	return self.criterion(logits[mask], labels[mask])
	return self.criterion(logits, labels)

	def compute_ned_type_loss(
	self,
	disambiguation_labels,
	re_ned_entities_logits,
	ned_type_logits,
	re_entities_logits,
	entity_types,
	mask,
	):
	if self.config.entity_type_loss and self.relation_disambiguation_loss:
	return self.criterion_type(
	re_ned_entities_logits[disambiguation_labels != -100],
	disambiguation_labels[disambiguation_labels != -100],
	)
	if self.config.entity_type_loss:
	return self.criterion_type(
	ned_type_logits[mask],
	disambiguation_labels[:, :, :entity_types][mask],
	)

	if self.relation_disambiguation_loss:
	return self.criterion_type(
	re_entities_logits[disambiguation_labels != -100],
	disambiguation_labels[disambiguation_labels != -100],
	)
	return 0

	def compute_relation_loss(self, relation_labels, re_logits):
	return self.compute_loss(
	re_logits, relation_labels, relation_labels.view(-1) != -100
	)

	def forward(
	self,
	input_ids: torch.Tensor,
	attention_mask: torch.Tensor,
	token_type_ids: torch.Tensor,
	prediction_mask: Optional[torch.Tensor] = None,
	special_symbols_mask: Optional[torch.Tensor] = None,
	special_symbols_mask_entities: Optional[torch.Tensor] = None,
	start_labels: Optional[torch.Tensor] = None,
	end_labels: Optional[torch.Tensor] = None,
	disambiguation_labels: Optional[torch.Tensor] = None,
	relation_labels: Optional[torch.Tensor] = None,
	relation_threshold: float = None,
	is_validation: bool = False,
	is_prediction: bool = False,
	use_predefined_spans: bool = False,
	*args,
	**kwargs,
	) -> Dict[str, Any]:
	relation_threshold = (
	self.config.threshold if relation_threshold is None else relation_threshold
	)

	batch_size = input_ids.shape[0]

	model_features = self._get_model_features(
	input_ids, attention_mask, token_type_ids
	)

	# named entity detection
	if use_predefined_spans:
	ned_start_logits, ned_start_probabilities, ned_start_predictions = (
	None,
	None,
	torch.zeros_like(start_labels),
	)
	ned_end_logits, ned_end_probabilities, ned_end_predictions = (
	None,
	None,
	torch.zeros_like(end_labels),
	)

	ned_start_predictions[start_labels > 0] = 1
	ned_end_predictions[end_labels > 0] = 1
	ned_end_predictions = ned_end_predictions[~(end_labels == -100).all(2)]
	ned_start_labels = start_labels
	ned_start_labels[start_labels > 0] = 1
	else:
	# start boundary prediction
	ned_start_logits = self.ned_start_classifier(model_features)
	if is_validation or is_prediction:
	ned_start_logits = self._mask_logits(
	ned_start_logits, prediction_mask
	) # why?
	ned_start_probabilities = torch.softmax(ned_start_logits, dim=-1)
	ned_start_predictions = ned_start_probabilities.argmax(dim=-1)

	# end boundary prediction
	ned_start_labels = (
	torch.zeros_like(start_labels) if start_labels is not None else None
	)

	# start_labels contain entity id at their position, we just need 1 for start of entity
	if ned_start_labels is not None:
	ned_start_labels[start_labels == -100] = -100
	ned_start_labels[start_labels > 0] = 1

	# compute end logits only if there are any start predictions.
	# For each start prediction, n end predictions are made
	ned_end_logits = self.compute_ned_end_logits(
	ned_start_predictions,
	ned_start_labels,
	model_features,
	prediction_mask,
	batch_size,
	True,
	)

	if ned_end_logits is not None:
	# For each start prediction, n end predictions are made based on
	# binary classification ie. argmax at each position.
	ned_end_probabilities = torch.softmax(ned_end_logits, dim=-1)
	ned_end_predictions = ned_end_probabilities.argmax(dim=-1)
	else:
	ned_end_logits, ned_end_probabilities = None, None
	ned_end_predictions = torch.zeros_like(ned_start_predictions)

	if is_prediction or is_validation:
	end_preds_count = ned_end_predictions.sum(1)
	# If there are no end predictions for a start prediction, remove the start prediction
	if (end_preds_count == 0).any() and (ned_start_predictions > 0).any():
	ned_start_predictions[ned_start_predictions == 1] = (
	end_preds_count != 0
	).long()
	ned_end_predictions = ned_end_predictions[end_preds_count != 0]

	if end_labels is not None:
	end_labels = end_labels[~(end_labels == -100).all(2)]

	start_position, end_position = (
	(start_labels, end_labels)
	if (not is_prediction and not is_validation)
	else (ned_start_predictions, ned_end_predictions)
	)

	start_counts = (start_position > 0).sum(1)
	if (start_counts > 0).any():
	ned_end_predictions = ned_end_predictions.split(start_counts.tolist())
	# limit to 30 predictions per document using start_counts, by setting all po after sum is 30 to 0
	# if is_validation or is_prediction:
	# ned_start_predictions[ned_start_predictions == 1] = start_counts
	# We can only predict relations if we have start and end predictions
	if (end_position > 0).sum() > 0:
	ends_count = (end_position > 0).sum(1)
	model_subject_features = torch.cat(
	[
	torch.repeat_interleave(
	model_features[start_position > 0], ends_count, dim=0
	), # start position features
	torch.repeat_interleave(model_features, start_counts, dim=0)[
	end_position > 0
	], # end position features
	],
	dim=-1,
	)
	ents_count = torch.nn.utils.rnn.pad_sequence(
	torch.split(ends_count, start_counts.tolist()),
	batch_first=True,
	padding_value=0,
	).sum(1)
	model_subject_features = torch.nn.utils.rnn.pad_sequence(
	torch.split(model_subject_features, ents_count.tolist()),
	batch_first=True,
	padding_value=-100,
	)

	# if is_validation or is_prediction:
	# model_subject_features = model_subject_features[:, :30, :]

	# entity disambiguation. Here relation_disambiguation_loss would only be useful to
	# reduce the number of candidate relations for the next step, but currently unused.
	if self.config.entity_type_loss or self.relation_disambiguation_loss:
	(re_ned_entities_logits) = self.compute_entity_logits(
	model_subject_features,
	model_features[
	special_symbols_mask \| special_symbols_mask_entities
	].view(batch_size, -1, model_features.shape[-1]),
	)
	entity_types = torch.sum(special_symbols_mask_entities, dim=1)[0].item()
	ned_type_logits = re_ned_entities_logits[:, :, :entity_types]
	re_entities_logits = re_ned_entities_logits[:, :, entity_types:]

	if self.config.entity_type_loss:
	ned_type_probabilities = torch.sigmoid(ned_type_logits)
	ned_type_predictions = ned_type_probabilities.argmax(dim=-1)

	if self.config.add_entity_embedding:
	special_symbols_representation = model_features[
	special_symbols_mask_entities
	].view(batch_size, entity_types, -1)

	entities_representation = torch.einsum(
	"bsp,bpe->bse",
	ned_type_probabilities,
	special_symbols_representation,
	)
	model_subject_features = torch.cat(
	[model_subject_features, entities_representation], dim=-1
	)
	re_entities_probabilities = torch.sigmoid(re_entities_logits)
	re_entities_predictions = re_entities_probabilities.round()
	else:
	(
	ned_type_logits,
	ned_type_probabilities,
	re_entities_logits,
	re_entities_probabilities,
	) = (None, None, None, None)
	ned_type_predictions, re_entities_predictions = (
	torch.zeros([batch_size, 1], dtype=torch.long).to(input_ids.device),
	torch.zeros([batch_size, 1], dtype=torch.long).to(input_ids.device),
	)

	# Compute relation logits
	re_logits = self.compute_relation_logits(
	model_subject_features,
	model_features[special_symbols_mask].view(
	batch_size, -1, model_features.shape[-1]
	),
	)

	re_probabilities = torch.softmax(re_logits, dim=-1)
	# we set a thresshold instead of argmax in cause it needs to be tweaked
	re_predictions = re_probabilities[:, :, :, :, 1] > relation_threshold
	re_probabilities = re_probabilities[:, :, :, :, 1]

	else:
	(
	ned_type_logits,
	ned_type_probabilities,
	re_entities_logits,
	re_entities_probabilities,
	) = (None, None, None, None)
	ned_type_predictions, re_entities_predictions = (
	torch.zeros([batch_size, 1], dtype=torch.long).to(input_ids.device),
	torch.zeros([batch_size, 1], dtype=torch.long).to(input_ids.device),
	)
	re_logits, re_probabilities, re_predictions = (
	torch.zeros(
	[batch_size, 1, 1, special_symbols_mask.sum(1)[0]], dtype=torch.long
	).to(input_ids.device),
	torch.zeros(
	[batch_size, 1, 1, special_symbols_mask.sum(1)[0]], dtype=torch.long
	).to(input_ids.device),
	torch.zeros(
	[batch_size, 1, 1, special_symbols_mask.sum(1)[0]], dtype=torch.long
	).to(input_ids.device),
	)

	# output build
	output_dict = dict(
	batch_size=batch_size,
	ned_start_logits=ned_start_logits,
	ned_start_probabilities=ned_start_probabilities,
	ned_start_predictions=ned_start_predictions,
	ned_end_logits=ned_end_logits,
	ned_end_probabilities=ned_end_probabilities,
	ned_end_predictions=ned_end_predictions,
	ned_type_logits=ned_type_logits,
	ned_type_probabilities=ned_type_probabilities,
	ned_type_predictions=ned_type_predictions,
	re_entities_logits=re_entities_logits,
	re_entities_probabilities=re_entities_probabilities,
	re_entities_predictions=re_entities_predictions,
	re_logits=re_logits,
	re_probabilities=re_probabilities,
	re_predictions=re_predictions,
	)

	if (
	start_labels is not None
	and end_labels is not None
	and relation_labels is not None
	and is_prediction is False
	):
	ned_start_loss = self.compute_loss(ned_start_logits, ned_start_labels)
	end_labels[end_labels > 0] = 1
	ned_end_loss = self.compute_loss(ned_end_logits, end_labels)
	if self.config.entity_type_loss or self.relation_disambiguation_loss:
	ned_type_loss = self.compute_ned_type_loss(
	disambiguation_labels,
	re_ned_entities_logits,
	ned_type_logits,
	re_entities_logits,
	entity_types,
	(model_subject_features != -100).all(2),
	)
	relation_loss = self.compute_relation_loss(relation_labels, re_logits)
	# compute loss. We can skip the relation loss if we are in the first epochs (optional)
	if self.config.entity_type_loss or self.relation_disambiguation_loss:
	output_dict["loss"] = (
	ned_start_loss + ned_end_loss + relation_loss + ned_type_loss
	) / 4
	output_dict["ned_type_loss"] = ned_type_loss
	else:
	output_dict["loss"] = ((1 / 20) * (ned_start_loss + ned_end_loss)) + (
	(9 / 10) * relation_loss
	)
	output_dict["ned_start_loss"] = ned_start_loss
	output_dict["ned_end_loss"] = ned_end_loss
	output_dict["re_loss"] = relation_loss

	return output_dict