# coding=utf-8
# Copyright 2018 Google AI, Google Brain and Carnegie Mellon University Authors and the HuggingFace Inc. team.
# Copyright (c) 2018, NVIDIA CORPORATION. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""
PyTorch XLNet model.
"""
import warnings
from dataclasses import dataclass
from typing import Callable, Optional, Union
import torch
from torch import nn
from torch.nn import BCEWithLogitsLoss, CrossEntropyLoss, MSELoss
from ...activations import ACT2FN, get_activation
from ...generation import GenerationMixin
from ...modeling_utils import PreTrainedModel
from ...pytorch_utils import apply_chunking_to_forward
from ...utils import ModelOutput, auto_docstring, logging
from .configuration_xlnet import XLNetConfig
logger = logging.get_logger(__name__)
def build_tf_xlnet_to_pytorch_map(model, config, tf_weights=None):
"""
A map of modules from TF to PyTorch. I use a map to keep the PyTorch model as identical to the original PyTorch
model as possible.
"""
tf_to_pt_map = {}
if hasattr(model, "transformer"):
if hasattr(model, "lm_loss"):
# We will load also the output bias
tf_to_pt_map["model/lm_loss/bias"] = model.lm_loss.bias
if hasattr(model, "sequence_summary") and "model/sequnece_summary/summary/kernel" in tf_weights:
# We will load also the sequence summary
tf_to_pt_map["model/sequnece_summary/summary/kernel"] = model.sequence_summary.summary.weight
tf_to_pt_map["model/sequnece_summary/summary/bias"] = model.sequence_summary.summary.bias
if (
hasattr(model, "logits_proj")
and config.finetuning_task is not None
and f"model/regression_{config.finetuning_task}/logit/kernel" in tf_weights
):
tf_to_pt_map[f"model/regression_{config.finetuning_task}/logit/kernel"] = model.logits_proj.weight
tf_to_pt_map[f"model/regression_{config.finetuning_task}/logit/bias"] = model.logits_proj.bias
# Now load the rest of the transformer
model = model.transformer
# Embeddings and output
tf_to_pt_map.update(
{
"model/transformer/word_embedding/lookup_table": model.word_embedding.weight,
"model/transformer/mask_emb/mask_emb": model.mask_emb,
}
)
# Transformer blocks
for i, b in enumerate(model.layer):
layer_str = f"model/transformer/layer_{i}/"
tf_to_pt_map.update(
{
layer_str + "rel_attn/LayerNorm/gamma": b.rel_attn.layer_norm.weight,
layer_str + "rel_attn/LayerNorm/beta": b.rel_attn.layer_norm.bias,
layer_str + "rel_attn/o/kernel": b.rel_attn.o,
layer_str + "rel_attn/q/kernel": b.rel_attn.q,
layer_str + "rel_attn/k/kernel": b.rel_attn.k,
layer_str + "rel_attn/r/kernel": b.rel_attn.r,
layer_str + "rel_attn/v/kernel": b.rel_attn.v,
layer_str + "ff/LayerNorm/gamma": b.ff.layer_norm.weight,
layer_str + "ff/LayerNorm/beta": b.ff.layer_norm.bias,
layer_str + "ff/layer_1/kernel": b.ff.layer_1.weight,
layer_str + "ff/layer_1/bias": b.ff.layer_1.bias,
layer_str + "ff/layer_2/kernel": b.ff.layer_2.weight,
layer_str + "ff/layer_2/bias": b.ff.layer_2.bias,
}
)
# Relative positioning biases
if config.untie_r:
r_r_list = []
r_w_list = []
r_s_list = []
seg_embed_list = []
for b in model.layer:
r_r_list.append(b.rel_attn.r_r_bias)
r_w_list.append(b.rel_attn.r_w_bias)
r_s_list.append(b.rel_attn.r_s_bias)
seg_embed_list.append(b.rel_attn.seg_embed)
else:
r_r_list = [model.r_r_bias]
r_w_list = [model.r_w_bias]
r_s_list = [model.r_s_bias]
seg_embed_list = [model.seg_embed]
tf_to_pt_map.update(
{
"model/transformer/r_r_bias": r_r_list,
"model/transformer/r_w_bias": r_w_list,
"model/transformer/r_s_bias": r_s_list,
"model/transformer/seg_embed": seg_embed_list,
}
)
return tf_to_pt_map
def load_tf_weights_in_xlnet(model, config, tf_path):
"""Load tf checkpoints in a pytorch model"""
try:
import numpy as np
import tensorflow as tf
except ImportError:
logger.error(
"Loading a TensorFlow models in PyTorch, requires TensorFlow to be installed. Please see "
"https://www.tensorflow.org/install/ for installation instructions."
)
raise
# Load weights from TF model
init_vars = tf.train.list_variables(tf_path)
tf_weights = {}
for name, shape in init_vars:
logger.info(f"Loading TF weight {name} with shape {shape}")
array = tf.train.load_variable(tf_path, name)
tf_weights[name] = array
# Build TF to PyTorch weights loading map
tf_to_pt_map = build_tf_xlnet_to_pytorch_map(model, config, tf_weights)
for name, pointer in tf_to_pt_map.items():
logger.info(f"Importing {name}")
if name not in tf_weights:
logger.info(f"{name} not in tf pre-trained weights, skipping")
continue
array = tf_weights[name]
# adam_v and adam_m are variables used in AdamWeightDecayOptimizer to calculated m and v
# which are not required for using pretrained model
if "kernel" in name and ("ff" in name or "summary" in name or "logit" in name):
logger.info("Transposing")
array = np.transpose(array)
if isinstance(pointer, list):
# Here we will split the TF weights
assert len(pointer) == array.shape[0], (
f"Pointer length {len(pointer)} and array length {array.shape[0]} mismatched"
)
for i, p_i in enumerate(pointer):
arr_i = array[i, ...]
try:
assert p_i.shape == arr_i.shape, (
f"Pointer shape {p_i.shape} and array shape {arr_i.shape} mismatched"
)
except AssertionError as e:
e.args += (p_i.shape, arr_i.shape)
raise
logger.info(f"Initialize PyTorch weight {name} for layer {i}")
p_i.data = torch.from_numpy(arr_i)
else:
try:
assert pointer.shape == array.shape, (
f"Pointer shape {pointer.shape} and array shape {array.shape} mismatched"
)
except AssertionError as e:
e.args += (pointer.shape, array.shape)
raise
logger.info(f"Initialize PyTorch weight {name}")
pointer.data = torch.from_numpy(array)
tf_weights.pop(name, None)
tf_weights.pop(name + "/Adam", None)
tf_weights.pop(name + "/Adam_1", None)
logger.info(f"Weights not copied to PyTorch model: {', '.join(tf_weights.keys())}")
return model
class XLNetRelativeAttention(nn.Module):
def __init__(self, config):
super().__init__()
if config.d_model % config.n_head != 0:
raise ValueError(
f"The hidden size ({config.d_model}) is not a multiple of the number of attention "
f"heads ({config.n_head}"
)
self.n_head = config.n_head
self.d_head = config.d_head
self.d_model = config.d_model
self.scale = 1 / (config.d_head**0.5)
self.q = nn.Parameter(torch.FloatTensor(config.d_model, self.n_head, self.d_head))
self.k = nn.Parameter(torch.FloatTensor(config.d_model, self.n_head, self.d_head))
self.v = nn.Parameter(torch.FloatTensor(config.d_model, self.n_head, self.d_head))
self.o = nn.Parameter(torch.FloatTensor(config.d_model, self.n_head, self.d_head))
self.r = nn.Parameter(torch.FloatTensor(config.d_model, self.n_head, self.d_head))
self.r_r_bias = nn.Parameter(torch.FloatTensor(self.n_head, self.d_head))
self.r_s_bias = nn.Parameter(torch.FloatTensor(self.n_head, self.d_head))
self.r_w_bias = nn.Parameter(torch.FloatTensor(self.n_head, self.d_head))
self.seg_embed = nn.Parameter(torch.FloatTensor(2, self.n_head, self.d_head))
self.layer_norm = nn.LayerNorm(config.d_model, eps=config.layer_norm_eps)
self.dropout = nn.Dropout(config.dropout)
def prune_heads(self, heads):
raise NotImplementedError
@staticmethod
def rel_shift(x, klen=-1):
"""perform relative shift to form the relative attention score."""
x_size = x.shape
x = x.reshape(x_size[1], x_size[0], x_size[2], x_size[3])
x = x[1:, ...]
x = x.reshape(x_size[0], x_size[1] - 1, x_size[2], x_size[3])
# x = x[:, 0:klen, :, :]
x = torch.index_select(x, 1, torch.arange(klen, device=x.device, dtype=torch.long))
return x
@staticmethod
def rel_shift_bnij(x, klen=-1):
x_size = x.shape
x = x.reshape(x_size[0], x_size[1], x_size[3], x_size[2])
x = x[:, :, 1:, :]
x = x.reshape(x_size[0], x_size[1], x_size[2], x_size[3] - 1)
# Note: the tensor-slice form was faster in my testing than torch.index_select
# However, tracing doesn't like the nature of the slice, and if klen changes
# during the run then it'll fail, whereas index_select will be fine.
x = torch.index_select(x, 3, torch.arange(klen, device=x.device, dtype=torch.long))
# x = x[:, :, :, :klen]
return x
def rel_attn_core(
self,
q_head,
k_head_h,
v_head_h,
k_head_r,
seg_mat=None,
attn_mask=None,
head_mask=None,
output_attentions=False,
):
"""Core relative positional attention operations."""
# content based attention score
ac = torch.einsum("ibnd,jbnd->bnij", q_head + self.r_w_bias, k_head_h)
# position based attention score
bd = torch.einsum("ibnd,jbnd->bnij", q_head + self.r_r_bias, k_head_r)
bd = self.rel_shift_bnij(bd, klen=ac.shape[3])
# segment based attention score
if seg_mat is None:
ef = 0
else:
ef = torch.einsum("ibnd,snd->ibns", q_head + self.r_s_bias, self.seg_embed)
ef = torch.einsum("ijbs,ibns->bnij", seg_mat, ef)
# merge attention scores and perform masking
attn_score = (ac + bd + ef) * self.scale
if attn_mask is not None:
# attn_score = attn_score * (1 - attn_mask) - 1e30 * attn_mask
if attn_mask.dtype == torch.float16:
attn_score = attn_score - 65500 * torch.einsum("ijbn->bnij", attn_mask)
else:
attn_score = attn_score - 1e30 * torch.einsum("ijbn->bnij", attn_mask)
# attention probability
attn_prob = nn.functional.softmax(attn_score, dim=3)
attn_prob = self.dropout(attn_prob)
# Mask heads if we want to
if head_mask is not None:
attn_prob = attn_prob * torch.einsum("ijbn->bnij", head_mask)
# attention output
attn_vec = torch.einsum("bnij,jbnd->ibnd", attn_prob, v_head_h)
if output_attentions:
return attn_vec, torch.einsum("bnij->ijbn", attn_prob)
return attn_vec
def post_attention(self, h, attn_vec, residual=True):
"""Post-attention processing."""
# post-attention projection (back to `d_model`)
attn_out = torch.einsum("ibnd,hnd->ibh", attn_vec, self.o)
attn_out = self.dropout(attn_out)
if residual:
attn_out = attn_out + h
output = self.layer_norm(attn_out)
return output
def forward(
self,
h,
g,
attn_mask_h,
attn_mask_g,
r,
seg_mat,
mems=None,
target_mapping=None,
head_mask=None,
output_attentions=False,
):
if g is not None:
# Two-stream attention with relative positional encoding.
# content based attention score
if mems is not None and mems.dim() > 1:
cat = torch.cat([mems, h], dim=0)
else:
cat = h
# content-based key head
k_head_h = torch.einsum("ibh,hnd->ibnd", cat, self.k)
# content-based value head
v_head_h = torch.einsum("ibh,hnd->ibnd", cat, self.v)
# position-based key head
k_head_r = torch.einsum("ibh,hnd->ibnd", r, self.r)
# h-stream
# content-stream query head
q_head_h = torch.einsum("ibh,hnd->ibnd", h, self.q)
# core attention ops
attn_vec_h = self.rel_attn_core(
q_head_h,
k_head_h,
v_head_h,
k_head_r,
seg_mat=seg_mat,
attn_mask=attn_mask_h,
head_mask=head_mask,
output_attentions=output_attentions,
)
if output_attentions:
attn_vec_h, attn_prob_h = attn_vec_h
# post processing
output_h = self.post_attention(h, attn_vec_h)
# g-stream
# query-stream query head
q_head_g = torch.einsum("ibh,hnd->ibnd", g, self.q)
# core attention ops
if target_mapping is not None:
q_head_g = torch.einsum("mbnd,mlb->lbnd", q_head_g, target_mapping)
attn_vec_g = self.rel_attn_core(
q_head_g,
k_head_h,
v_head_h,
k_head_r,
seg_mat=seg_mat,
attn_mask=attn_mask_g,
head_mask=head_mask,
output_attentions=output_attentions,
)
if output_attentions:
attn_vec_g, attn_prob_g = attn_vec_g
attn_vec_g = torch.einsum("lbnd,mlb->mbnd", attn_vec_g, target_mapping)
else:
attn_vec_g = self.rel_attn_core(
q_head_g,
k_head_h,
v_head_h,
k_head_r,
seg_mat=seg_mat,
attn_mask=attn_mask_g,
head_mask=head_mask,
output_attentions=output_attentions,
)
if output_attentions:
attn_vec_g, attn_prob_g = attn_vec_g
# post processing
output_g = self.post_attention(g, attn_vec_g)
if output_attentions:
attn_prob = attn_prob_h, attn_prob_g
else:
# Multi-head attention with relative positional encoding
if mems is not None and mems.dim() > 1:
cat = torch.cat([mems, h], dim=0)
else:
cat = h
# content heads
q_head_h = torch.einsum("ibh,hnd->ibnd", h, self.q)
k_head_h = torch.einsum("ibh,hnd->ibnd", cat, self.k)
v_head_h = torch.einsum("ibh,hnd->ibnd", cat, self.v)
# positional heads
# type casting for fp16 support
k_head_r = torch.einsum("ibh,hnd->ibnd", r.type(self.r.dtype), self.r)
# core attention ops
attn_vec = self.rel_attn_core(
q_head_h,
k_head_h,
v_head_h,
k_head_r,
seg_mat=seg_mat,
attn_mask=attn_mask_h,
head_mask=head_mask,
output_attentions=output_attentions,
)
if output_attentions:
attn_vec, attn_prob = attn_vec
# post processing
output_h = self.post_attention(h, attn_vec)
output_g = None
outputs = (output_h, output_g)
if output_attentions:
outputs = outputs + (attn_prob,)
return outputs
class XLNetFeedForward(nn.Module):
def __init__(self, config):
super().__init__()
self.layer_norm = nn.LayerNorm(config.d_model, eps=config.layer_norm_eps)
self.layer_1 = nn.Linear(config.d_model, config.d_inner)
self.layer_2 = nn.Linear(config.d_inner, config.d_model)
self.dropout = nn.Dropout(config.dropout)
if isinstance(config.ff_activation, str):
self.activation_function = ACT2FN[config.ff_activation]
else:
self.activation_function = config.ff_activation
def forward(self, inp):
output = inp
output = self.layer_1(output)
output = self.activation_function(output)
output = self.dropout(output)
output = self.layer_2(output)
output = self.dropout(output)
output = self.layer_norm(output + inp)
return output
class XLNetLayer(nn.Module):
def __init__(self, config):
super().__init__()
self.rel_attn = XLNetRelativeAttention(config)
self.ff = XLNetFeedForward(config)
self.dropout = nn.Dropout(config.dropout)
self.chunk_size_feed_forward = config.chunk_size_feed_forward
self.seq_len_dim = 1
def forward(
self,
output_h,
output_g,
attn_mask_h,
attn_mask_g,
r,
seg_mat,
mems=None,
target_mapping=None,
head_mask=None,
output_attentions=False,
):
outputs = self.rel_attn(
output_h,
output_g,
attn_mask_h,
attn_mask_g,
r,
seg_mat,
mems=mems,
target_mapping=target_mapping,
head_mask=head_mask,
output_attentions=output_attentions,
)
output_h, output_g = outputs[:2]
if output_g is not None:
output_g = apply_chunking_to_forward(
self.ff_chunk, self.chunk_size_feed_forward, self.seq_len_dim, output_g
)
output_h = apply_chunking_to_forward(self.ff_chunk, self.chunk_size_feed_forward, self.seq_len_dim, output_h)
outputs = (output_h, output_g) + outputs[2:] # Add again attentions if there are there
return outputs
def ff_chunk(self, output_x):
output_x = self.ff(output_x)
return output_x
# Copied from transformers.models.xlm.modeling_xlm.XLMPoolerStartLogits with XLM->XLNet
class XLNetPoolerStartLogits(nn.Module):
"""
Compute SQuAD start logits from sequence hidden states.
Args:
config ([`XLNetConfig`]):
The config used by the model, will be used to grab the `hidden_size` of the model.
"""
def __init__(self, config: XLNetConfig):
super().__init__()
self.dense = nn.Linear(config.hidden_size, 1)
def forward(
self, hidden_states: torch.FloatTensor, p_mask: Optional[torch.FloatTensor] = None
) -> torch.FloatTensor:
"""
Args:
hidden_states (`torch.FloatTensor` of shape `(batch_size, seq_len, hidden_size)`):
The final hidden states of the model.
p_mask (`torch.FloatTensor` of shape `(batch_size, seq_len)`, *optional*):
Mask for tokens at invalid position, such as query and special symbols (PAD, SEP, CLS). 1.0 means token
should be masked.
Returns:
`torch.FloatTensor`: The start logits for SQuAD.
"""
x = self.dense(hidden_states).squeeze(-1)
if p_mask is not None:
if p_mask.dtype == torch.float16:
x = x * (1 - p_mask) - 65500 * p_mask
else:
x = x * (1 - p_mask) - 1e30 * p_mask
return x
# Copied from transformers.models.xlm.modeling_xlm.XLMPoolerEndLogits with XLM->XLNet
class XLNetPoolerEndLogits(nn.Module):
"""
Compute SQuAD end logits from sequence hidden states.
Args:
config ([`XLNetConfig`]):
The config used by the model, will be used to grab the `hidden_size` of the model and the `layer_norm_eps`
to use.
"""
def __init__(self, config: XLNetConfig):
super().__init__()
self.dense_0 = nn.Linear(config.hidden_size * 2, config.hidden_size)
self.activation = nn.Tanh()
self.LayerNorm = nn.LayerNorm(config.hidden_size, eps=config.layer_norm_eps)
self.dense_1 = nn.Linear(config.hidden_size, 1)
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:
"""
Args:
hidden_states (`torch.FloatTensor` of shape `(batch_size, seq_len, hidden_size)`):
The final hidden states of the model.
start_states (`torch.FloatTensor` of shape `(batch_size, seq_len, hidden_size)`, *optional*):
The hidden states of the first tokens for the labeled span.
start_positions (`torch.LongTensor` of shape `(batch_size,)`, *optional*):
The position of the first token for the labeled span.
p_mask (`torch.FloatTensor` of shape `(batch_size, seq_len)`, *optional*):
Mask for tokens at invalid position, such as query and special symbols (PAD, SEP, CLS). 1.0 means token
should be masked.
One of `start_states` or `start_positions` should be not `None`. If both are set, `start_positions` overrides
`start_states`.
Returns:
`torch.FloatTensor`: The end logits for SQuAD.
"""
assert start_states is not None or start_positions is not None, (
"One of start_states, start_positions should be not None"
)
if start_positions is not None:
slen, hsz = hidden_states.shape[-2:]
start_positions = start_positions[:, None, None].expand(-1, -1, hsz) # shape (bsz, 1, hsz)
start_states = hidden_states.gather(-2, start_positions) # shape (bsz, 1, hsz)
start_states = start_states.expand(-1, slen, -1) # shape (bsz, slen, hsz)
x = self.dense_0(torch.cat([hidden_states, start_states], dim=-1))
x = self.activation(x)
x = self.LayerNorm(x)
x = self.dense_1(x).squeeze(-1)
if p_mask is not None:
if p_mask.dtype == torch.float16:
x = x * (1 - p_mask) - 65500 * p_mask
else:
x = x * (1 - p_mask) - 1e30 * p_mask
return x
# Copied from transformers.models.xlm.modeling_xlm.XLMPoolerAnswerClass with XLM->XLNet
class XLNetPoolerAnswerClass(nn.Module):
"""
Compute SQuAD 2.0 answer class from classification and start tokens hidden states.
Args:
config ([`XLNetConfig`]):
The config used by the model, will be used to grab the `hidden_size` of the model.
"""
def __init__(self, config: XLNetConfig):
super().__init__()
self.dense_0 = nn.Linear(config.hidden_size * 2, config.hidden_size)
self.activation = nn.Tanh()
self.dense_1 = nn.Linear(config.hidden_size, 1, bias=False)
def forward(
self,
hidden_states: torch.FloatTensor,
start_states: Optional[torch.FloatTensor] = None,
start_positions: Optional[torch.LongTensor] = None,
cls_index: Optional[torch.LongTensor] = None,
) -> torch.FloatTensor:
"""
Args:
hidden_states (`torch.FloatTensor` of shape `(batch_size, seq_len, hidden_size)`):
The final hidden states of the model.
start_states (`torch.FloatTensor` of shape `(batch_size, seq_len, hidden_size)`, *optional*):
The hidden states of the first tokens for the labeled span.
start_positions (`torch.LongTensor` of shape `(batch_size,)`, *optional*):
The position of the first token for the labeled span.
cls_index (`torch.LongTensor` of shape `(batch_size,)`, *optional*):
Position of the CLS token for each sentence in the batch. If `None`, takes the last token.
One of `start_states` or `start_positions` should be not `None`. If both are set, `start_positions` overrides
`start_states`.
Returns:
`torch.FloatTensor`: The SQuAD 2.0 answer class.
"""
# No dependency on end_feature so that we can obtain one single `cls_logits` for each sample.
hsz = hidden_states.shape[-1]
assert start_states is not None or start_positions is not None, (
"One of start_states, start_positions should be not None"
)
if start_positions is not None:
start_positions = start_positions[:, None, None].expand(-1, -1, hsz) # shape (bsz, 1, hsz)
start_states = hidden_states.gather(-2, start_positions).squeeze(-2) # shape (bsz, hsz)
if cls_index is not None:
cls_index = cls_index[:, None, None].expand(-1, -1, hsz) # shape (bsz, 1, hsz)
cls_token_state = hidden_states.gather(-2, cls_index).squeeze(-2) # shape (bsz, hsz)
else:
cls_token_state = hidden_states[:, -1, :] # shape (bsz, hsz)
x = self.dense_0(torch.cat([start_states, cls_token_state], dim=-1))
x = self.activation(x)
x = self.dense_1(x).squeeze(-1)
return x
# Copied from transformers.models.xlm.modeling_xlm.XLMSequenceSummary with XLM->XLNet
class XLNetSequenceSummary(nn.Module):
r"""
Compute a single vector summary of a sequence hidden states.
Args:
config ([`XLNetConfig`]):
The config used by the model. Relevant arguments in the config class of the model are (refer to the actual
config class of your model for the default values it uses):
- **summary_type** (`str`) -- The method to use to make this summary. Accepted values are:
- `"last"` -- Take the last token hidden state (like XLNet)
- `"first"` -- Take the first token hidden state (like Bert)
- `"mean"` -- Take the mean of all tokens hidden states
- `"cls_index"` -- Supply a Tensor of classification token position (GPT/GPT-2)
- `"attn"` -- Not implemented now, use multi-head attention
- **summary_use_proj** (`bool`) -- Add a projection after the vector extraction.
- **summary_proj_to_labels** (`bool`) -- If `True`, the projection outputs to `config.num_labels` classes
(otherwise to `config.hidden_size`).
- **summary_activation** (`Optional[str]`) -- Set to `"tanh"` to add a tanh activation to the output,
another string or `None` will add no activation.
- **summary_first_dropout** (`float`) -- Optional dropout probability before the projection and activation.
- **summary_last_dropout** (`float`)-- Optional dropout probability after the projection and activation.
"""
def __init__(self, config: XLNetConfig):
super().__init__()
self.summary_type = getattr(config, "summary_type", "last")
if self.summary_type == "attn":
# We should use a standard multi-head attention module with absolute positional embedding for that.
# Cf. https://github.com/zihangdai/xlnet/blob/master/modeling.py#L253-L276
# We can probably just use the multi-head attention module of PyTorch >=1.1.0
raise NotImplementedError
self.summary = nn.Identity()
if hasattr(config, "summary_use_proj") and config.summary_use_proj:
if hasattr(config, "summary_proj_to_labels") and config.summary_proj_to_labels and config.num_labels > 0:
num_classes = config.num_labels
else:
num_classes = config.hidden_size
self.summary = nn.Linear(config.hidden_size, num_classes)
activation_string = getattr(config, "summary_activation", None)
self.activation: Callable = get_activation(activation_string) if activation_string else nn.Identity()
self.first_dropout = nn.Identity()
if hasattr(config, "summary_first_dropout") and config.summary_first_dropout > 0:
self.first_dropout = nn.Dropout(config.summary_first_dropout)
self.last_dropout = nn.Identity()
if hasattr(config, "summary_last_dropout") and config.summary_last_dropout > 0:
self.last_dropout = nn.Dropout(config.summary_last_dropout)
def forward(
self, hidden_states: torch.FloatTensor, cls_index: Optional[torch.LongTensor] = None
) -> torch.FloatTensor:
"""
Compute a single vector summary of a sequence hidden states.
Args:
hidden_states (`torch.FloatTensor` of shape `[batch_size, seq_len, hidden_size]`):
The hidden states of the last layer.
cls_index (`torch.LongTensor` of shape `[batch_size]` or `[batch_size, ...]` where ... are optional leading dimensions of `hidden_states`, *optional*):
Used if `summary_type == "cls_index"` and takes the last token of the sequence as classification token.
Returns:
`torch.FloatTensor`: The summary of the sequence hidden states.
"""
if self.summary_type == "last":
output = hidden_states[:, -1]
elif self.summary_type == "first":
output = hidden_states[:, 0]
elif self.summary_type == "mean":
output = hidden_states.mean(dim=1)
elif self.summary_type == "cls_index":
if cls_index is None:
cls_index = torch.full_like(
hidden_states[..., :1, :],
hidden_states.shape[-2] - 1,
dtype=torch.long,
)
else:
cls_index = cls_index.unsqueeze(-1).unsqueeze(-1)
cls_index = cls_index.expand((-1,) * (cls_index.dim() - 1) + (hidden_states.size(-1),))
# shape of cls_index: (bsz, XX, 1, hidden_size) where XX are optional leading dim of hidden_states
output = hidden_states.gather(-2, cls_index).squeeze(-2) # shape (bsz, XX, hidden_size)
elif self.summary_type == "attn":
raise NotImplementedError
output = self.first_dropout(output)
output = self.summary(output)
output = self.activation(output)
output = self.last_dropout(output)
return output
@auto_docstring
class XLNetPreTrainedModel(PreTrainedModel):
config: XLNetConfig
load_tf_weights = load_tf_weights_in_xlnet
base_model_prefix = "transformer"
def _init_weights(self, module):
"""Initialize the weights."""
if isinstance(module, nn.Linear):
# Slightly different from the TF version which uses truncated_normal for initialization
# cf https://github.com/pytorch/pytorch/pull/5617
module.weight.data.normal_(mean=0.0, std=self.config.initializer_range)
if module.bias is not None:
module.bias.data.zero_()
elif isinstance(module, nn.Embedding):
module.weight.data.normal_(mean=0.0, std=self.config.initializer_range)
if module.padding_idx is not None:
module.weight.data[module.padding_idx].zero_()
elif isinstance(module, nn.LayerNorm):
module.bias.data.zero_()
module.weight.data.fill_(1.0)
elif isinstance(module, XLNetRelativeAttention):
for param in [
module.q,
module.k,
module.v,
module.o,
module.r,
module.r_r_bias,
module.r_s_bias,
module.r_w_bias,
module.seg_embed,
]:
param.data.normal_(mean=0.0, std=self.config.initializer_range)
elif isinstance(module, XLNetModel):
module.mask_emb.data.normal_(mean=0.0, std=self.config.initializer_range)
@dataclass
@auto_docstring(
custom_intro="""
Output type of [`XLNetModel`].
"""
)
class XLNetModelOutput(ModelOutput):
r"""
last_hidden_state (`torch.FloatTensor` of shape `(batch_size, num_predict, hidden_size)`):
Sequence of hidden-states at the last layer of the model.
`num_predict` corresponds to `target_mapping.shape[1]`. If `target_mapping` is `None`, then `num_predict`
corresponds to `sequence_length`.
mems (`list[torch.FloatTensor]` of length `config.n_layers`):
Contains pre-computed hidden-states. Can be used (see `mems` input) to speed up sequential decoding. The
token ids which have their past given to this model should not be passed as `input_ids` as they have
already been computed.
"""
last_hidden_state: torch.FloatTensor
mems: Optional[list[torch.FloatTensor]] = None
hidden_states: Optional[tuple[torch.FloatTensor, ...]] = None
attentions: Optional[tuple[torch.FloatTensor, ...]] = None
@dataclass
@auto_docstring(
custom_intro="""
Output type of [`XLNetLMHeadModel`].
"""
)
class XLNetLMHeadModelOutput(ModelOutput):
r"""
loss (`torch.FloatTensor` of shape *(1,)*, *optional*, returned when `labels` is provided):
Language modeling loss (for next-token prediction).
logits (`torch.FloatTensor` of shape `(batch_size, num_predict, config.vocab_size)`):
Prediction scores of the language modeling head (scores for each vocabulary token before SoftMax).
`num_predict` corresponds to `target_mapping.shape[1]`. If `target_mapping` is `None`, then `num_predict`
corresponds to `sequence_length`.
mems (`list[torch.FloatTensor]` of length `config.n_layers`):
Contains pre-computed hidden-states. Can be used (see `mems` input) to speed up sequential decoding. The
token ids which have their past given to this model should not be passed as `input_ids` as they have
already been computed.
"""
loss: Optional[torch.FloatTensor] = None
logits: Optional[torch.FloatTensor] = None
mems: Optional[list[torch.FloatTensor]] = None
hidden_states: Optional[tuple[torch.FloatTensor, ...]] = None
attentions: Optional[tuple[torch.FloatTensor, ...]] = None
@dataclass
@auto_docstring(
custom_intro="""
Output type of [`XLNetForSequenceClassification`].
"""
)
class XLNetForSequenceClassificationOutput(ModelOutput):
r"""
loss (`torch.FloatTensor` of shape `(1,)`, *optional*, returned when `label` is provided):
Classification (or regression if config.num_labels==1) loss.
logits (`torch.FloatTensor` of shape `(batch_size, config.num_labels)`):
Classification (or regression if config.num_labels==1) scores (before SoftMax).
mems (`list[torch.FloatTensor]` of length `config.n_layers`):
Contains pre-computed hidden-states. Can be used (see `mems` input) to speed up sequential decoding. The
token ids which have their past given to this model should not be passed as `input_ids` as they have
already been computed.
"""
loss: Optional[torch.FloatTensor] = None
logits: Optional[torch.FloatTensor] = None
mems: Optional[list[torch.FloatTensor]] = None
hidden_states: Optional[tuple[torch.FloatTensor, ...]] = None
attentions: Optional[tuple[torch.FloatTensor, ...]] = None
@dataclass
@auto_docstring(
custom_intro="""
Output type of [`XLNetForTokenClassificationOutput`].
"""
)
class XLNetForTokenClassificationOutput(ModelOutput):
r"""
loss (`torch.FloatTensor` of shape `(1,)`, *optional*, returned when `labels` is provided):
Classification loss.
logits (`torch.FloatTensor` of shape `(batch_size, sequence_length, config.num_labels)`):
Classification scores (before SoftMax).
mems (`list[torch.FloatTensor]` of length `config.n_layers`):
Contains pre-computed hidden-states. Can be used (see `mems` input) to speed up sequential decoding. The
token ids which have their past given to this model should not be passed as `input_ids` as they have
already been computed.
"""
loss: Optional[torch.FloatTensor] = None
logits: Optional[torch.FloatTensor] = None
mems: Optional[list[torch.FloatTensor]] = None
hidden_states: Optional[tuple[torch.FloatTensor, ...]] = None
attentions: Optional[tuple[torch.FloatTensor, ...]] = None
@dataclass
@auto_docstring(
custom_intro="""
Output type of [`XLNetForMultipleChoice`].
"""
)
class XLNetForMultipleChoiceOutput(ModelOutput):
r"""
loss (`torch.FloatTensor` of shape *(1,)*, *optional*, returned when `labels` is provided):
Classification loss.
logits (`torch.FloatTensor` of shape `(batch_size, num_choices)`):
*num_choices* is the second dimension of the input tensors. (see *input_ids* above).
Classification scores (before SoftMax).
mems (`list[torch.FloatTensor]` of length `config.n_layers`):
Contains pre-computed hidden-states. Can be used (see `mems` input) to speed up sequential decoding. The
token ids which have their past given to this model should not be passed as `input_ids` as they have
already been computed.
"""
loss: Optional[torch.FloatTensor] = None
logits: Optional[torch.FloatTensor] = None
mems: Optional[list[torch.FloatTensor]] = None
hidden_states: Optional[tuple[torch.FloatTensor, ...]] = None
attentions: Optional[tuple[torch.FloatTensor, ...]] = None
@dataclass
@auto_docstring(
custom_intro="""
Output type of [`XLNetForQuestionAnsweringSimple`].
"""
)
class XLNetForQuestionAnsweringSimpleOutput(ModelOutput):
r"""
loss (`torch.FloatTensor` of shape `(1,)`, *optional*, returned when `labels` is provided):
Total span extraction loss is the sum of a Cross-Entropy for the start and end positions.
start_logits (`torch.FloatTensor` of shape `(batch_size, sequence_length,)`):
Span-start scores (before SoftMax).
end_logits (`torch.FloatTensor` of shape `(batch_size, sequence_length,)`):
Span-end scores (before SoftMax).
mems (`list[torch.FloatTensor]` of length `config.n_layers`):
Contains pre-computed hidden-states. Can be used (see `mems` input) to speed up sequential decoding. The
token ids which have their past given to this model should not be passed as `input_ids` as they have
already been computed.
"""
loss: Optional[torch.FloatTensor] = None
start_logits: Optional[torch.FloatTensor] = None
end_logits: Optional[torch.FloatTensor] = None
mems: Optional[list[torch.FloatTensor]] = None
hidden_states: Optional[tuple[torch.FloatTensor, ...]] = None
attentions: Optional[tuple[torch.FloatTensor, ...]] = None
@dataclass
@auto_docstring(
custom_intro="""
Output type of [`XLNetForQuestionAnswering`].
"""
)
class XLNetForQuestionAnsweringOutput(ModelOutput):
r"""
loss (`torch.FloatTensor` of shape `(1,)`, *optional*, returned if both `start_positions` and `end_positions` are provided):
Classification loss as the sum of start token, end token (and is_impossible if provided) classification
losses.
start_top_log_probs (`torch.FloatTensor` of shape `(batch_size, config.start_n_top)`, *optional*, returned if `start_positions` or `end_positions` is not provided):
Log probabilities for the top config.start_n_top start token possibilities (beam-search).
start_top_index (`torch.LongTensor` of shape `(batch_size, config.start_n_top)`, *optional*, returned if `start_positions` or `end_positions` is not provided):
Indices for the top config.start_n_top start token possibilities (beam-search).
end_top_log_probs (`torch.FloatTensor` of shape `(batch_size, config.start_n_top * config.end_n_top)`, *optional*, returned if `start_positions` or `end_positions` is not provided):
Log probabilities for the top `config.start_n_top * config.end_n_top` end token possibilities
(beam-search).
end_top_index (`torch.LongTensor` of shape `(batch_size, config.start_n_top * config.end_n_top)`, *optional*, returned if `start_positions` or `end_positions` is not provided):
Indices for the top `config.start_n_top * config.end_n_top` end token possibilities (beam-search).
cls_logits (`torch.FloatTensor` of shape `(batch_size,)`, *optional*, returned if `start_positions` or `end_positions` is not provided):
Log probabilities for the `is_impossible` label of the answers.
mems (`list[torch.FloatTensor]` of length `config.n_layers`):
Contains pre-computed hidden-states. Can be used (see `mems` input) to speed up sequential decoding. The
token ids which have their past given to this model should not be passed as `input_ids` as they have
already been computed.
"""
loss: Optional[torch.FloatTensor] = None
start_top_log_probs: Optional[torch.FloatTensor] = None
start_top_index: Optional[torch.LongTensor] = None
end_top_log_probs: Optional[torch.FloatTensor] = None
end_top_index: Optional[torch.LongTensor] = None
cls_logits: Optional[torch.FloatTensor] = None
mems: Optional[list[torch.FloatTensor]] = None
hidden_states: Optional[tuple[torch.FloatTensor, ...]] = None
attentions: Optional[tuple[torch.FloatTensor, ...]] = None
@auto_docstring
class XLNetModel(XLNetPreTrainedModel):
def __init__(self, config):
super().__init__(config)
self.mem_len = config.mem_len
self.reuse_len = config.reuse_len
self.d_model = config.d_model
self.same_length = config.same_length
self.attn_type = config.attn_type
self.bi_data = config.bi_data
self.clamp_len = config.clamp_len
self.n_layer = config.n_layer
self.word_embedding = nn.Embedding(config.vocab_size, config.d_model)
self.mask_emb = nn.Parameter(torch.FloatTensor(1, 1, config.d_model))
self.layer = nn.ModuleList([XLNetLayer(config) for _ in range(config.n_layer)])
self.dropout = nn.Dropout(config.dropout)
# Initialize weights and apply final processing
self.post_init()
def get_input_embeddings(self):
return self.word_embedding
def set_input_embeddings(self, new_embeddings):
self.word_embedding = new_embeddings
def _prune_heads(self, heads_to_prune):
raise NotImplementedError
def create_mask(self, qlen, mlen):
"""
Creates causal attention mask. Float mask where 1.0 indicates masked, 0.0 indicates not-masked.
Args:
qlen: Sequence length
mlen: Mask length
::
same_length=False: same_length=True: < qlen > < qlen >
^ [0 0 0 0 0 1 1 1 1] [0 0 0 0 0 1 1 1 1]
[0 0 0 0 0 0 1 1 1] [1 0 0 0 0 0 1 1 1]
qlen [0 0 0 0 0 0 0 1 1] [1 1 0 0 0 0 0 1 1]
[0 0 0 0 0 0 0 0 1] [1 1 1 0 0 0 0 0 1]
v [0 0 0 0 0 0 0 0 0] [1 1 1 1 0 0 0 0 0]
"""
mask = torch.ones((qlen, qlen + mlen), device=self.device)
if self.same_length:
mask_lo = mask[:, :qlen].tril(-1)
mask.triu_(mlen + 1)
mask[:, :qlen] += mask_lo
else:
mask.triu_(mlen + 1)
return mask
def cache_mem(self, curr_out, prev_mem):
# cache hidden states into memory.
if self.reuse_len is not None and self.reuse_len > 0:
curr_out = curr_out[: self.reuse_len]
if self.mem_len is None or self.mem_len == 0:
# If `use_mems` is active but no `mem_len` is defined, the model behaves like GPT-2 at inference time
# and returns all of the past and current hidden states.
cutoff = 0
else:
# If `use_mems` is active and `mem_len` is defined, the model returns the last `mem_len` hidden
# states. This is the preferred setting for training and long-form generation.
cutoff = -self.mem_len
if prev_mem is None:
# if `use_mems` is active and `mem_len` is defined, the model
new_mem = curr_out[cutoff:]
else:
new_mem = torch.cat([prev_mem, curr_out], dim=0)[cutoff:]
return new_mem.detach()
@staticmethod
def positional_embedding(pos_seq, inv_freq, bsz=None):
sinusoid_inp = torch.einsum("i,d->id", pos_seq, inv_freq)
pos_emb = torch.cat([torch.sin(sinusoid_inp), torch.cos(sinusoid_inp)], dim=-1)
pos_emb = pos_emb[:, None, :]
if bsz is not None:
pos_emb = pos_emb.expand(-1, bsz, -1)
return pos_emb
def relative_positional_encoding(self, qlen, klen, bsz=None):
# create relative positional encoding.
freq_seq = torch.arange(0, self.d_model, 2.0, dtype=torch.int64).float()
inv_freq = 1 / torch.pow(10000, (freq_seq / self.d_model))
if self.attn_type == "bi":
# beg, end = klen - 1, -qlen
beg, end = klen, -qlen
elif self.attn_type == "uni":
# beg, end = klen - 1, -1
beg, end = klen, -1
else:
raise ValueError(f"Unknown `attn_type` {self.attn_type}.")
if self.bi_data:
fwd_pos_seq = torch.arange(beg, end, -1.0, dtype=torch.int64).float()
bwd_pos_seq = torch.arange(-beg, -end, 1.0, dtype=torch.int64).float()
if self.clamp_len > 0:
fwd_pos_seq = fwd_pos_seq.clamp(-self.clamp_len, self.clamp_len)
bwd_pos_seq = bwd_pos_seq.clamp(-self.clamp_len, self.clamp_len)
if bsz is not None:
fwd_pos_emb = self.positional_embedding(fwd_pos_seq, inv_freq, bsz // 2)
bwd_pos_emb = self.positional_embedding(bwd_pos_seq, inv_freq, bsz // 2)
else:
fwd_pos_emb = self.positional_embedding(fwd_pos_seq, inv_freq)
bwd_pos_emb = self.positional_embedding(bwd_pos_seq, inv_freq)
pos_emb = torch.cat([fwd_pos_emb, bwd_pos_emb], dim=1)
else:
fwd_pos_seq = torch.arange(beg, end, -1.0, dtype=torch.int64).float()
if self.clamp_len > 0:
fwd_pos_seq = fwd_pos_seq.clamp(-self.clamp_len, self.clamp_len)
pos_emb = self.positional_embedding(fwd_pos_seq, inv_freq, bsz)
return pos_emb
@auto_docstring
def forward(
self,
input_ids: Optional[torch.Tensor] = None,
attention_mask: Optional[torch.Tensor] = None,
mems: Optional[torch.Tensor] = None,
perm_mask: Optional[torch.Tensor] = None,
target_mapping: Optional[torch.Tensor] = None,
token_type_ids: Optional[torch.Tensor] = None,
input_mask: Optional[torch.Tensor] = None,
head_mask: Optional[torch.Tensor] = None,
inputs_embeds: Optional[torch.Tensor] = None,
use_mems: Optional[bool] = None,
output_attentions: Optional[bool] = None,
output_hidden_states: Optional[bool] = None,
return_dict: Optional[bool] = None,
**kwargs, # delete after depreciation warning is removed
) -> Union[tuple, XLNetModelOutput]:
r"""
mems (`list[torch.FloatTensor]` of length `config.n_layers`):
Contains pre-computed hidden-states (see `mems` output below) . Can be used to speed up sequential
decoding. The token ids which have their past given to this model should not be passed as `input_ids` as
they have already been computed.
`use_mems` has to be set to `True` to make use of `mems`.
perm_mask (`torch.FloatTensor` of shape `(batch_size, sequence_length, sequence_length)`, *optional*):
Mask to indicate the attention pattern for each input token with values selected in `[0, 1]`:
- if `perm_mask[k, i, j] = 0`, i attend to j in batch k;
- if `perm_mask[k, i, j] = 1`, i does not attend to j in batch k.
If not set, each token attends to all the others (full bidirectional attention). Only used during
pretraining (to define factorization order) or for sequential decoding (generation).
target_mapping (`torch.FloatTensor` of shape `(batch_size, num_predict, sequence_length)`, *optional*):
Mask to indicate the output tokens to use. If `target_mapping[k, i, j] = 1`, the i-th predict in batch k is
on the j-th token. Only used during pretraining for partial prediction or for sequential decoding
(generation).
input_mask (`torch.FloatTensor` of shape `batch_size, sequence_length`, *optional*):
Mask to avoid performing attention on padding token indices. Negative of `attention_mask`, i.e. with 0 for
real tokens and 1 for padding which is kept for compatibility with the original code base.
Mask values selected in `[0, 1]`:
- 1 for tokens that are **masked**,
- 0 for tokens that are **not masked**.
You can only uses one of `input_mask` and `attention_mask`.
use_mems (`bool`, *optional*):
Whether to use memory states to speed up sequential decoding. If set to `True`, the model will use the hidden
states from previous forward passes to compute attention, which can significantly improve performance for
sequential decoding tasks.
"""
output_attentions = output_attentions if output_attentions is not None else self.config.output_attentions
output_hidden_states = (
output_hidden_states if output_hidden_states is not None else self.config.output_hidden_states
)
return_dict = return_dict if return_dict is not None else self.config.use_return_dict
if "use_cache" in kwargs:
warnings.warn(
"The `use_cache` argument is deprecated and will be removed in a future version, use `use_mems`"
" instead.",
FutureWarning,
)
use_mems = kwargs["use_cache"]
if self.training:
use_mems = use_mems if use_mems is not None else self.config.use_mems_train
else:
use_mems = use_mems if use_mems is not None else self.config.use_mems_eval
# the original code for XLNet uses shapes [len, bsz] with the batch dimension at the end
# but we want a unified interface in the library with the batch size on the first dimension
# so we move here the first dimension (batch) to the end
if input_ids is not None and inputs_embeds is not None:
raise ValueError("You cannot specify both input_ids and inputs_embeds at the same time")
elif input_ids is not None:
input_ids = input_ids.transpose(0, 1).contiguous()
qlen, bsz = input_ids.shape[0], input_ids.shape[1]
elif inputs_embeds is not None:
inputs_embeds = inputs_embeds.transpose(0, 1).contiguous()
qlen, bsz = inputs_embeds.shape[0], inputs_embeds.shape[1]
else:
raise ValueError("You have to specify either input_ids or inputs_embeds")
token_type_ids = token_type_ids.transpose(0, 1).contiguous() if token_type_ids is not None else None
input_mask = input_mask.transpose(0, 1).contiguous() if input_mask is not None else None
attention_mask = attention_mask.transpose(0, 1).contiguous() if attention_mask is not None else None
perm_mask = perm_mask.permute(1, 2, 0).contiguous() if perm_mask is not None else None
target_mapping = target_mapping.permute(1, 2, 0).contiguous() if target_mapping is not None else None
mlen = mems[0].shape[0] if mems is not None and mems[0] is not None else 0
klen = mlen + qlen
dtype_float = self.dtype
device = self.device
# Attention mask
# causal attention mask
if self.attn_type == "uni":
attn_mask = self.create_mask(qlen, mlen)
attn_mask = attn_mask[:, :, None, None]
elif self.attn_type == "bi":
attn_mask = None
else:
raise ValueError(f"Unsupported attention type: {self.attn_type}")
# data mask: input mask & perm mask
assert input_mask is None or attention_mask is None, "You can only use one of input_mask (uses 1 for padding) "
"or attention_mask (uses 0 for padding, added for compatibility with BERT). Please choose one."
if input_mask is None and attention_mask is not None:
input_mask = 1.0 - attention_mask
if input_mask is not None and perm_mask is not None:
data_mask = input_mask[None] + perm_mask
elif input_mask is not None and perm_mask is None:
data_mask = input_mask[None]
elif input_mask is None and perm_mask is not None:
data_mask = perm_mask
else:
data_mask = None
if data_mask is not None:
# all mems can be attended to
if mlen > 0:
mems_mask = torch.zeros([data_mask.shape[0], mlen, bsz]).to(data_mask)
data_mask = torch.cat([mems_mask, data_mask], dim=1)
if attn_mask is None:
attn_mask = data_mask[:, :, :, None]
else:
attn_mask += data_mask[:, :, :, None]
if attn_mask is not None:
attn_mask = (attn_mask > 0).to(dtype_float)
if attn_mask is not None:
non_tgt_mask = -torch.eye(qlen).to(attn_mask)
if mlen > 0:
non_tgt_mask = torch.cat([torch.zeros([qlen, mlen]).to(attn_mask), non_tgt_mask], dim=-1)
non_tgt_mask = ((attn_mask + non_tgt_mask[:, :, None, None]) > 0).to(attn_mask)
else:
non_tgt_mask = None
# Word embeddings and prepare h & g hidden states
if inputs_embeds is not None:
word_emb_k = inputs_embeds
else:
word_emb_k = self.word_embedding(input_ids)
output_h = self.dropout(word_emb_k)
if target_mapping is not None:
word_emb_q = self.mask_emb.expand(target_mapping.shape[0], bsz, -1)
# else: # We removed the inp_q input which was same as target mapping
# inp_q_ext = inp_q[:, :, None]
# word_emb_q = inp_q_ext * self.mask_emb + (1 - inp_q_ext) * word_emb_k
output_g = self.dropout(word_emb_q)
else:
output_g = None
# Segment embedding
if token_type_ids is not None:
# Convert `token_type_ids` to one-hot `seg_mat`
if mlen > 0:
mem_pad = torch.zeros([mlen, bsz], dtype=torch.long, device=device)
cat_ids = torch.cat([mem_pad, token_type_ids], dim=0)
else:
cat_ids = token_type_ids
# `1` indicates not in the same segment [qlen x klen x bsz]
seg_mat = (token_type_ids[:, None] != cat_ids[None, :]).long()
seg_mat = nn.functional.one_hot(seg_mat, num_classes=2).to(dtype_float)
else:
seg_mat = None
# Positional encoding
pos_emb = self.relative_positional_encoding(qlen, klen, bsz=bsz)
pos_emb = pos_emb.to(output_h.device)
pos_emb = self.dropout(pos_emb)
# Prepare head mask if needed
# 1.0 in head_mask indicate we keep the head
# attention_probs has shape bsz x n_heads x N x N
# input head_mask has shape [num_heads] or [num_hidden_layers x num_heads] (a head_mask for each layer)
# and head_mask is converted to shape [num_hidden_layers x qlen x klen x bsz x n_head]
if head_mask is not None:
if head_mask.dim() == 1:
head_mask = head_mask.unsqueeze(0).unsqueeze(0).unsqueeze(0).unsqueeze(0)
head_mask = head_mask.expand(self.n_layer, -1, -1, -1, -1)
elif head_mask.dim() == 2:
head_mask = head_mask.unsqueeze(1).unsqueeze(1).unsqueeze(1)
head_mask = head_mask.to(
dtype=next(self.parameters()).dtype
) # switch to float if need + fp16 compatibility
else:
head_mask = [None] * self.n_layer
new_mems = ()
if mems is None:
mems = [None] * len(self.layer)
attentions = [] if output_attentions else None
hidden_states = [] if output_hidden_states else None
for i, layer_module in enumerate(self.layer):
if use_mems:
# cache new mems
new_mems = new_mems + (self.cache_mem(output_h, mems[i]),)
if output_hidden_states:
hidden_states.append((output_h, output_g) if output_g is not None else output_h)
outputs = layer_module(
output_h,
output_g,
attn_mask_h=non_tgt_mask,
attn_mask_g=attn_mask,
r=pos_emb,
seg_mat=seg_mat,
mems=mems[i],
target_mapping=target_mapping,
head_mask=head_mask[i],
output_attentions=output_attentions,
)
output_h, output_g = outputs[:2]
if output_attentions:
attentions.append(outputs[2])
# Add last hidden state
if output_hidden_states:
hidden_states.append((output_h, output_g) if output_g is not None else output_h)
output = self.dropout(output_g if output_g is not None else output_h)
# Prepare outputs, we transpose back here to shape [bsz, len, hidden_dim] (cf. beginning of forward() method)
output = output.permute(1, 0, 2).contiguous()
if not use_mems:
new_mems = None
if output_hidden_states:
if output_g is not None:
hidden_states = tuple(h.permute(1, 0, 2).contiguous() for hs in hidden_states for h in hs)
else:
hidden_states = tuple(hs.permute(1, 0, 2).contiguous() for hs in hidden_states)
if output_attentions:
if target_mapping is not None:
# when target_mapping is provided, there are 2-tuple of attentions
attentions = tuple(
tuple(att_stream.permute(2, 3, 0, 1).contiguous() for att_stream in t) for t in attentions
)
else:
attentions = tuple(t.permute(2, 3, 0, 1).contiguous() for t in attentions)
if not return_dict:
return tuple(v for v in [output, new_mems, hidden_states, attentions] if v is not None)
return XLNetModelOutput(
last_hidden_state=output, mems=new_mems, hidden_states=hidden_states, attentions=attentions
)
@auto_docstring(
custom_intro="""
XLNet Model with a language modeling head on top (linear layer with weights tied to the input embeddings).
"""
)
class XLNetLMHeadModel(XLNetPreTrainedModel, GenerationMixin):
_tied_weights_keys = ["lm_loss.weight"]
def __init__(self, config):
super().__init__(config)
self.attn_type = config.attn_type
self.same_length = config.same_length
self.transformer = XLNetModel(config)
self.lm_loss = nn.Linear(config.d_model, config.vocab_size, bias=True)
# Initialize weights and apply final processing
self.post_init()
def get_output_embeddings(self):
return self.lm_loss
def set_output_embeddings(self, new_embeddings):
self.lm_loss = new_embeddings
def prepare_inputs_for_generation(self, input_ids, past_key_values=None, use_mems=None, **kwargs):
# Overwritten -- this model has unique input preparation
# Add dummy token at the end (no attention on this one)
effective_batch_size = input_ids.shape[0]
dummy_token = torch.zeros((effective_batch_size, 1), dtype=torch.long, device=input_ids.device)
# At every pass, the attention values for the new token and the two last generated tokens
# are computed, the rest is reloaded from the `past` cache. A purely auto-regressive model would have
# offset = 1; offset = 2 seems to have slightly better computation.
offset = 2
if past_key_values:
input_ids = torch.cat([input_ids[:, -offset:], dummy_token], dim=1)
else:
input_ids = torch.cat([input_ids, dummy_token], dim=1)
# Build permutation mask so that previous tokens don't see last token
sequence_length = input_ids.shape[1]
perm_mask = torch.zeros(
(effective_batch_size, sequence_length, sequence_length), dtype=torch.float, device=input_ids.device
)
perm_mask[:, :, -1] = 1.0
# We'll only predict the last token
target_mapping = torch.zeros(
(effective_batch_size, 1, sequence_length), dtype=torch.float, device=input_ids.device
)
target_mapping[:, 0, -1] = 1.0
inputs = {
"input_ids": input_ids,
"perm_mask": perm_mask,
"target_mapping": target_mapping,
"use_mems": use_mems,
}
# if past is defined in model kwargs then use it for faster decoding
if past_key_values:
inputs["mems"] = tuple(layer_past[:-offset, :, :] for layer_past in past_key_values)
return inputs
@auto_docstring
def forward(
self,
input_ids: Optional[torch.Tensor] = None,
attention_mask: Optional[torch.Tensor] = None,
mems: Optional[torch.Tensor] = None,
perm_mask: Optional[torch.Tensor] = None,
target_mapping: Optional[torch.Tensor] = None,
token_type_ids: Optional[torch.Tensor] = None,
input_mask: Optional[torch.Tensor] = None,
head_mask: Optional[torch.Tensor] = None,
inputs_embeds: Optional[torch.Tensor] = None,
labels: Optional[torch.Tensor] = None,
use_mems: Optional[bool] = None,
output_attentions: Optional[bool] = None,
output_hidden_states: Optional[bool] = None,
return_dict: Optional[bool] = None,
**kwargs, # delete when `use_cache` is removed in XLNetModel
) -> Union[tuple, XLNetLMHeadModelOutput]:
r"""
mems (`list[torch.FloatTensor]` of length `config.n_layers`):
Contains pre-computed hidden-states (see `mems` output below) . Can be used to speed up sequential
decoding. The token ids which have their past given to this model should not be passed as `input_ids` as
they have already been computed.
`use_mems` has to be set to `True` to make use of `mems`.
perm_mask (`torch.FloatTensor` of shape `(batch_size, sequence_length, sequence_length)`, *optional*):
Mask to indicate the attention pattern for each input token with values selected in `[0, 1]`:
- if `perm_mask[k, i, j] = 0`, i attend to j in batch k;
- if `perm_mask[k, i, j] = 1`, i does not attend to j in batch k.
If not set, each token attends to all the others (full bidirectional attention). Only used during
pretraining (to define factorization order) or for sequential decoding (generation).
target_mapping (`torch.FloatTensor` of shape `(batch_size, num_predict, sequence_length)`, *optional*):
Mask to indicate the output tokens to use. If `target_mapping[k, i, j] = 1`, the i-th predict in batch k is
on the j-th token. Only used during pretraining for partial prediction or for sequential decoding
(generation).
input_mask (`torch.FloatTensor` of shape `batch_size, sequence_length`, *optional*):
Mask to avoid performing attention on padding token indices. Negative of `attention_mask`, i.e. with 0 for
real tokens and 1 for padding which is kept for compatibility with the original code base.
Mask values selected in `[0, 1]`:
- 1 for tokens that are **masked**,
- 0 for tokens that are **not masked**.
You can only uses one of `input_mask` and `attention_mask`.
labels (`torch.LongTensor` of shape `(batch_size, num_predict)`, *optional*):
Labels for masked language modeling. `num_predict` corresponds to `target_mapping.shape[1]`. If
`target_mapping` is `None`, then `num_predict` corresponds to `sequence_length`.
The labels should correspond to the masked input words that should be predicted and depends on
`target_mapping`. Note in order to perform standard auto-regressive language modeling a ** token has
to be added to the `input_ids` (see the `prepare_inputs_for_generation` function and examples below)
Indices are selected in `[-100, 0, ..., config.vocab_size]` All labels set to `-100` are ignored, the loss
is only computed for labels in `[0, ..., config.vocab_size]`
use_mems (`bool`, *optional*):
Whether to use memory states to speed up sequential decoding. If set to `True`, the model will use the hidden
states from previous forward passes to compute attention, which can significantly improve performance for
sequential decoding tasks.
Examples:
```python
>>> from transformers import AutoTokenizer, XLNetLMHeadModel
>>> import torch
>>> tokenizer = AutoTokenizer.from_pretrained("xlnet/xlnet-large-cased")
>>> model = XLNetLMHeadModel.from_pretrained("xlnet/xlnet-large-cased")
>>> # We show how to setup inputs to predict a next token using a bi-directional context.
>>> input_ids = torch.tensor(
... tokenizer.encode("Hello, my dog is very ", add_special_tokens=False)
... ).unsqueeze(
... 0
... ) # We will predict the masked token
>>> perm_mask = torch.zeros((1, input_ids.shape[1], input_ids.shape[1]), dtype=torch.float)
>>> perm_mask[:, :, -1] = 1.0 # Previous tokens don't see last token
>>> target_mapping = torch.zeros(
... (1, 1, input_ids.shape[1]), dtype=torch.float
... ) # Shape [1, 1, seq_length] => let's predict one token
>>> target_mapping[
... 0, 0, -1
... ] = 1.0 # Our first (and only) prediction will be the last token of the sequence (the masked token)
>>> outputs = model(input_ids, perm_mask=perm_mask, target_mapping=target_mapping)
>>> next_token_logits = outputs[
... 0
... ] # Output has shape [target_mapping.size(0), target_mapping.size(1), config.vocab_size]
>>> # The same way can the XLNetLMHeadModel be used to be trained by standard auto-regressive language modeling.
>>> input_ids = torch.tensor(
... tokenizer.encode("Hello, my dog is very ", add_special_tokens=False)
... ).unsqueeze(
... 0
... ) # We will predict the masked token
>>> labels = torch.tensor(tokenizer.encode("cute", add_special_tokens=False)).unsqueeze(0)
>>> assert labels.shape[0] == 1, "only one word will be predicted"
>>> perm_mask = torch.zeros((1, input_ids.shape[1], input_ids.shape[1]), dtype=torch.float)
>>> perm_mask[
... :, :, -1
... ] = 1.0 # Previous tokens don't see last token as is done in standard auto-regressive lm training
>>> target_mapping = torch.zeros(
... (1, 1, input_ids.shape[1]), dtype=torch.float
... ) # Shape [1, 1, seq_length] => let's predict one token
>>> target_mapping[
... 0, 0, -1
... ] = 1.0 # Our first (and only) prediction will be the last token of the sequence (the masked token)
>>> outputs = model(input_ids, perm_mask=perm_mask, target_mapping=target_mapping, labels=labels)
>>> loss = outputs.loss
>>> next_token_logits = (
... outputs.logits
... ) # Logits have shape [target_mapping.size(0), target_mapping.size(1), config.vocab_size]
```"""
return_dict = return_dict if return_dict is not None else self.config.use_return_dict
transformer_outputs = self.transformer(
input_ids,
attention_mask=attention_mask,
mems=mems,
perm_mask=perm_mask,
target_mapping=target_mapping,
token_type_ids=token_type_ids,
input_mask=input_mask,
head_mask=head_mask,
inputs_embeds=inputs_embeds,
use_mems=use_mems,
output_attentions=output_attentions,
output_hidden_states=output_hidden_states,
return_dict=return_dict,
**kwargs,
)
logits = self.lm_loss(transformer_outputs[0])
loss = None
if labels is not None:
# Flatten the tokens
loss_fct = CrossEntropyLoss()
loss = loss_fct(logits.view(-1, logits.size(-1)), labels.view(-1))
if not return_dict:
output = (logits,) + transformer_outputs[1:]
return ((loss,) + output) if loss is not None else output
return XLNetLMHeadModelOutput(
loss=loss,
logits=logits,
mems=transformer_outputs.mems,
hidden_states=transformer_outputs.hidden_states,
attentions=transformer_outputs.attentions,
)
@staticmethod
def _reorder_cache(mems: list[torch.Tensor], beam_idx: torch.Tensor) -> list[torch.Tensor]:
"""
This function is used to re-order the `mems` cache if [`~PreTrainedModel.beam_search`] or
[`~PreTrainedModel.beam_sample`] is called. This is required to match `mems` with the correct beam_idx at every
generation step.
"""
return [layer_past.index_select(1, beam_idx.to(layer_past.device)) for layer_past in mems]
@auto_docstring(
custom_intro="""
XLNet Model with a sequence classification/regression head on top (a linear layer on top of the pooled output) e.g.
for GLUE tasks.
"""
)
class XLNetForSequenceClassification(XLNetPreTrainedModel):
def __init__(self, config):
super().__init__(config)
self.num_labels = config.num_labels
self.config = config
self.transformer = XLNetModel(config)
self.sequence_summary = XLNetSequenceSummary(config)
self.logits_proj = nn.Linear(config.d_model, config.num_labels)
# Initialize weights and apply final processing
self.post_init()
@auto_docstring
def forward(
self,
input_ids: Optional[torch.Tensor] = None,
attention_mask: Optional[torch.Tensor] = None,
mems: Optional[torch.Tensor] = None,
perm_mask: Optional[torch.Tensor] = None,
target_mapping: Optional[torch.Tensor] = None,
token_type_ids: Optional[torch.Tensor] = None,
input_mask: Optional[torch.Tensor] = None,
head_mask: Optional[torch.Tensor] = None,
inputs_embeds: Optional[torch.Tensor] = None,
labels: Optional[torch.Tensor] = None,
use_mems: Optional[bool] = None,
output_attentions: Optional[bool] = None,
output_hidden_states: Optional[bool] = None,
return_dict: Optional[bool] = None,
**kwargs, # delete when `use_cache` is removed in XLNetModel
) -> Union[tuple, XLNetForSequenceClassificationOutput]:
r"""
mems (`list[torch.FloatTensor]` of length `config.n_layers`):
Contains pre-computed hidden-states (see `mems` output below) . Can be used to speed up sequential
decoding. The token ids which have their past given to this model should not be passed as `input_ids` as
they have already been computed.
`use_mems` has to be set to `True` to make use of `mems`.
perm_mask (`torch.FloatTensor` of shape `(batch_size, sequence_length, sequence_length)`, *optional*):
Mask to indicate the attention pattern for each input token with values selected in `[0, 1]`:
- if `perm_mask[k, i, j] = 0`, i attend to j in batch k;
- if `perm_mask[k, i, j] = 1`, i does not attend to j in batch k.
If not set, each token attends to all the others (full bidirectional attention). Only used during
pretraining (to define factorization order) or for sequential decoding (generation).
target_mapping (`torch.FloatTensor` of shape `(batch_size, num_predict, sequence_length)`, *optional*):
Mask to indicate the output tokens to use. If `target_mapping[k, i, j] = 1`, the i-th predict in batch k is
on the j-th token. Only used during pretraining for partial prediction or for sequential decoding
(generation).
input_mask (`torch.FloatTensor` of shape `batch_size, sequence_length`, *optional*):
Mask to avoid performing attention on padding token indices. Negative of `attention_mask`, i.e. with 0 for
real tokens and 1 for padding which is kept for compatibility with the original code base.
Mask values selected in `[0, 1]`:
- 1 for tokens that are **masked**,
- 0 for tokens that are **not masked**.
You can only uses one of `input_mask` and `attention_mask`.
labels (`torch.LongTensor` of shape `(batch_size,)`, *optional*):
Labels for computing the sequence classification/regression loss. Indices should be in `[0, ...,
config.num_labels - 1]`. If `config.num_labels == 1` a regression loss is computed (Mean-Square loss), If
`config.num_labels > 1` a classification loss is computed (Cross-Entropy).
use_mems (`bool`, *optional*):
Whether to use memory states to speed up sequential decoding. If set to `True`, the model will use the hidden
states from previous forward passes to compute attention, which can significantly improve performance for
sequential decoding tasks.
"""
return_dict = return_dict if return_dict is not None else self.config.use_return_dict
transformer_outputs = self.transformer(
input_ids,
attention_mask=attention_mask,
mems=mems,
perm_mask=perm_mask,
target_mapping=target_mapping,
token_type_ids=token_type_ids,
input_mask=input_mask,
head_mask=head_mask,
inputs_embeds=inputs_embeds,
use_mems=use_mems,
output_attentions=output_attentions,
output_hidden_states=output_hidden_states,
return_dict=return_dict,
**kwargs,
)
output = transformer_outputs[0]
output = self.sequence_summary(output)
logits = self.logits_proj(output)
loss = None
if labels is not None:
if self.config.problem_type is None:
if self.num_labels == 1:
self.config.problem_type = "regression"
elif self.num_labels > 1 and (labels.dtype == torch.long or labels.dtype == torch.int):
self.config.problem_type = "single_label_classification"
else:
self.config.problem_type = "multi_label_classification"
if self.config.problem_type == "regression":
loss_fct = MSELoss()
if self.num_labels == 1:
loss = loss_fct(logits.squeeze(), labels.squeeze())
else:
loss = loss_fct(logits, labels)
elif self.config.problem_type == "single_label_classification":
loss_fct = CrossEntropyLoss()
loss = loss_fct(logits.view(-1, self.num_labels), labels.view(-1))
elif self.config.problem_type == "multi_label_classification":
loss_fct = BCEWithLogitsLoss()
loss = loss_fct(logits, labels)
if not return_dict:
output = (logits,) + transformer_outputs[1:]
return ((loss,) + output) if loss is not None else output
return XLNetForSequenceClassificationOutput(
loss=loss,
logits=logits,
mems=transformer_outputs.mems,
hidden_states=transformer_outputs.hidden_states,
attentions=transformer_outputs.attentions,
)
@auto_docstring
class XLNetForTokenClassification(XLNetPreTrainedModel):
def __init__(self, config):
super().__init__(config)
self.num_labels = config.num_labels
self.transformer = XLNetModel(config)
self.classifier = nn.Linear(config.hidden_size, config.num_labels)
# Initialize weights and apply final processing
self.post_init()
@auto_docstring
def forward(
self,
input_ids: Optional[torch.Tensor] = None,
attention_mask: Optional[torch.Tensor] = None,
mems: Optional[torch.Tensor] = None,
perm_mask: Optional[torch.Tensor] = None,
target_mapping: Optional[torch.Tensor] = None,
token_type_ids: Optional[torch.Tensor] = None,
input_mask: Optional[torch.Tensor] = None,
head_mask: Optional[torch.Tensor] = None,
inputs_embeds: Optional[torch.Tensor] = None,
labels: Optional[torch.Tensor] = None,
use_mems: Optional[bool] = None,
output_attentions: Optional[bool] = None,
output_hidden_states: Optional[bool] = None,
return_dict: Optional[bool] = None,
**kwargs, # delete when `use_cache` is removed in XLNetModel
) -> Union[tuple, XLNetForTokenClassificationOutput]:
r"""
mems (`list[torch.FloatTensor]` of length `config.n_layers`):
Contains pre-computed hidden-states (see `mems` output below) . Can be used to speed up sequential
decoding. The token ids which have their past given to this model should not be passed as `input_ids` as
they have already been computed.
`use_mems` has to be set to `True` to make use of `mems`.
perm_mask (`torch.FloatTensor` of shape `(batch_size, sequence_length, sequence_length)`, *optional*):
Mask to indicate the attention pattern for each input token with values selected in `[0, 1]`:
- if `perm_mask[k, i, j] = 0`, i attend to j in batch k;
- if `perm_mask[k, i, j] = 1`, i does not attend to j in batch k.
If not set, each token attends to all the others (full bidirectional attention). Only used during
pretraining (to define factorization order) or for sequential decoding (generation).
target_mapping (`torch.FloatTensor` of shape `(batch_size, num_predict, sequence_length)`, *optional*):
Mask to indicate the output tokens to use. If `target_mapping[k, i, j] = 1`, the i-th predict in batch k is
on the j-th token. Only used during pretraining for partial prediction or for sequential decoding
(generation).
input_mask (`torch.FloatTensor` of shape `batch_size, sequence_length`, *optional*):
Mask to avoid performing attention on padding token indices. Negative of `attention_mask`, i.e. with 0 for
real tokens and 1 for padding which is kept for compatibility with the original code base.
Mask values selected in `[0, 1]`:
- 1 for tokens that are **masked**,
- 0 for tokens that are **not masked**.
You can only uses one of `input_mask` and `attention_mask`.
labels (`torch.LongTensor` of shape `(batch_size,)`, *optional*):
Labels for computing the multiple choice classification loss. Indices should be in `[0, ..., num_choices]`
where *num_choices* is the size of the second dimension of the input tensors. (see *input_ids* above)
use_mems (`bool`, *optional*):
Whether to use memory states to speed up sequential decoding. If set to `True`, the model will use the hidden
states from previous forward passes to compute attention, which can significantly improve performance for
sequential decoding tasks.emory states to speed up sequential decoding. If set to `True`, the model will use the hidden
states from previous forward passes to compute attention, which can significantly improve performance for
sequential decoding tasks.
"""
return_dict = return_dict if return_dict is not None else self.config.use_return_dict
outputs = self.transformer(
input_ids,
attention_mask=attention_mask,
mems=mems,
perm_mask=perm_mask,
target_mapping=target_mapping,
token_type_ids=token_type_ids,
input_mask=input_mask,
head_mask=head_mask,
inputs_embeds=inputs_embeds,
use_mems=use_mems,
output_attentions=output_attentions,
output_hidden_states=output_hidden_states,
return_dict=return_dict,
)
sequence_output = outputs[0]
logits = self.classifier(sequence_output)
loss = None
if labels is not None:
loss_fct = CrossEntropyLoss()
loss = loss_fct(logits.view(-1, self.num_labels), labels.view(-1))
if not return_dict:
output = (logits,) + outputs[1:]
return ((loss,) + output) if loss is not None else output
return XLNetForTokenClassificationOutput(
loss=loss,
logits=logits,
mems=outputs.mems,
hidden_states=outputs.hidden_states,
attentions=outputs.attentions,
)
@auto_docstring
class XLNetForMultipleChoice(XLNetPreTrainedModel):
def __init__(self, config):
super().__init__(config)
self.transformer = XLNetModel(config)
self.sequence_summary = XLNetSequenceSummary(config)
self.logits_proj = nn.Linear(config.d_model, 1)
# Initialize weights and apply final processing
self.post_init()
@auto_docstring
def forward(
self,
input_ids: Optional[torch.Tensor] = None,
token_type_ids: Optional[torch.Tensor] = None,
input_mask: Optional[torch.Tensor] = None,
attention_mask: Optional[torch.Tensor] = None,
mems: Optional[torch.Tensor] = None,
perm_mask: Optional[torch.Tensor] = None,
target_mapping: Optional[torch.Tensor] = None,
head_mask: Optional[torch.Tensor] = None,
inputs_embeds: Optional[torch.Tensor] = None,
labels: Optional[torch.Tensor] = None,
use_mems: Optional[bool] = None,
output_attentions: Optional[bool] = None,
output_hidden_states: Optional[bool] = None,
return_dict: Optional[bool] = None,
**kwargs, # delete when `use_cache` is removed in XLNetModel
) -> Union[tuple, XLNetForMultipleChoiceOutput]:
r"""
input_ids (`torch.LongTensor` of shape `(batch_size, num_choices, sequence_length)`):
Indices of input sequence tokens in the vocabulary.
Indices can be obtained using [`AutoTokenizer`]. See [`PreTrainedTokenizer.encode`] and
[`PreTrainedTokenizer.__call__`] for details.
[What are input IDs?](../glossary#input-ids)
token_type_ids (`torch.LongTensor` of shape `(batch_size, num_choices, sequence_length)`, *optional*):
Segment token indices to indicate first and second portions of the inputs. Indices are selected in `[0,
1]`:
- 0 corresponds to a *sentence A* token,
- 1 corresponds to a *sentence B* token.
[What are token type IDs?](../glossary#token-type-ids)
input_mask (`torch.FloatTensor` of shape `batch_size, num_choices, sequence_length`, *optional*):
Mask to avoid performing attention on padding token indices. Negative of `attention_mask`, i.e. with 0 for
real tokens and 1 for padding which is kept for compatibility with the original code base.
Mask values selected in `[0, 1]`:
- 1 for tokens that are **masked**,
- 0 for tokens that are **not masked**.
You can only uses one of `input_mask` and `attention_mask`.
mems (`list[torch.FloatTensor]` of length `config.n_layers`):
Contains pre-computed hidden-states (see `mems` output below) . Can be used to speed up sequential
decoding. The token ids which have their past given to this model should not be passed as `input_ids` as
they have already been computed.
`use_mems` has to be set to `True` to make use of `mems`.
perm_mask (`torch.FloatTensor` of shape `(batch_size, sequence_length, sequence_length)`, *optional*):
Mask to indicate the attention pattern for each input token with values selected in `[0, 1]`:
- if `perm_mask[k, i, j] = 0`, i attend to j in batch k;
- if `perm_mask[k, i, j] = 1`, i does not attend to j in batch k.
If not set, each token attends to all the others (full bidirectional attention). Only used during
pretraining (to define factorization order) or for sequential decoding (generation).
target_mapping (`torch.FloatTensor` of shape `(batch_size, num_predict, sequence_length)`, *optional*):
Mask to indicate the output tokens to use. If `target_mapping[k, i, j] = 1`, the i-th predict in batch k is
on the j-th token. Only used during pretraining for partial prediction or for sequential decoding
(generation).
inputs_embeds (`torch.FloatTensor` of shape `(batch_size, num_choices, sequence_length, hidden_size)`, *optional*):
Optionally, instead of passing `input_ids` you can choose to directly pass an embedded representation. This
is useful if you want more control over how to convert `input_ids` indices into associated vectors than the
model's internal embedding lookup matrix.
labels (`torch.LongTensor` of shape `(batch_size,)`, *optional*):
Labels for computing the multiple choice classification loss. Indices should be in `[0, ...,
use_mems (`bool`, *optional*):
Whether to use memory states to speed up sequential decoding. If set to `True`, the model will use the hidden
states from previous forward passes to compute attention, which can significantly improve performance for
sequential decoding tasks.
"""
return_dict = return_dict if return_dict is not None else self.config.use_return_dict
num_choices = input_ids.shape[1] if input_ids is not None else inputs_embeds.shape[1]
flat_input_ids = input_ids.view(-1, input_ids.size(-1)) if input_ids is not None else None
flat_token_type_ids = token_type_ids.view(-1, token_type_ids.size(-1)) if token_type_ids is not None else None
flat_attention_mask = attention_mask.view(-1, attention_mask.size(-1)) if attention_mask is not None else None
flat_input_mask = input_mask.view(-1, input_mask.size(-1)) if input_mask is not None else None
flat_inputs_embeds = (
inputs_embeds.view(-1, inputs_embeds.size(-2), inputs_embeds.size(-1))
if inputs_embeds is not None
else None
)
transformer_outputs = self.transformer(
flat_input_ids,
token_type_ids=flat_token_type_ids,
input_mask=flat_input_mask,
attention_mask=flat_attention_mask,
mems=mems,
perm_mask=perm_mask,
target_mapping=target_mapping,
head_mask=head_mask,
inputs_embeds=flat_inputs_embeds,
use_mems=use_mems,
output_attentions=output_attentions,
output_hidden_states=output_hidden_states,
return_dict=return_dict,
**kwargs,
)
output = transformer_outputs[0]
output = self.sequence_summary(output)
logits = self.logits_proj(output)
reshaped_logits = logits.view(-1, num_choices)
loss = None
if labels is not None:
loss_fct = CrossEntropyLoss()
loss = loss_fct(reshaped_logits, labels.view(-1))
if not return_dict:
output = (reshaped_logits,) + transformer_outputs[1:]
return ((loss,) + output) if loss is not None else output
return XLNetForMultipleChoiceOutput(
loss=loss,
logits=reshaped_logits,
mems=transformer_outputs.mems,
hidden_states=transformer_outputs.hidden_states,
attentions=transformer_outputs.attentions,
)
@auto_docstring(
custom_intro="""
XLNet Model with a span classification head on top for extractive question-answering tasks like SQuAD (a linear
layers on top of the hidden-states output to compute `span start logits` and `span end logits`).
"""
)
class XLNetForQuestionAnsweringSimple(XLNetPreTrainedModel):
def __init__(self, config):
super().__init__(config)
self.num_labels = config.num_labels
self.transformer = XLNetModel(config)
self.qa_outputs = nn.Linear(config.hidden_size, config.num_labels)
# Initialize weights and apply final processing
self.post_init()
@auto_docstring
def forward(
self,
input_ids: Optional[torch.Tensor] = None,
attention_mask: Optional[torch.Tensor] = None,
mems: Optional[torch.Tensor] = None,
perm_mask: Optional[torch.Tensor] = None,
target_mapping: Optional[torch.Tensor] = None,
token_type_ids: Optional[torch.Tensor] = None,
input_mask: Optional[torch.Tensor] = None,
head_mask: Optional[torch.Tensor] = None,
inputs_embeds: Optional[torch.Tensor] = None,
start_positions: Optional[torch.Tensor] = None,
end_positions: Optional[torch.Tensor] = None,
use_mems: Optional[bool] = None,
output_attentions: Optional[bool] = None,
output_hidden_states: Optional[bool] = None,
return_dict: Optional[bool] = None,
**kwargs, # delete when `use_cache` is removed in XLNetModel
) -> Union[tuple, XLNetForQuestionAnsweringSimpleOutput]:
r"""
mems (`list[torch.FloatTensor]` of length `config.n_layers`):
Contains pre-computed hidden-states (see `mems` output below) . Can be used to speed up sequential
decoding. The token ids which have their past given to this model should not be passed as `input_ids` as
they have already been computed.
`use_mems` has to be set to `True` to make use of `mems`.
perm_mask (`torch.FloatTensor` of shape `(batch_size, sequence_length, sequence_length)`, *optional*):
Mask to indicate the attention pattern for each input token with values selected in `[0, 1]`:
- if `perm_mask[k, i, j] = 0`, i attend to j in batch k;
- if `perm_mask[k, i, j] = 1`, i does not attend to j in batch k.
If not set, each token attends to all the others (full bidirectional attention). Only used during
pretraining (to define factorization order) or for sequential decoding (generation).
target_mapping (`torch.FloatTensor` of shape `(batch_size, num_predict, sequence_length)`, *optional*):
Mask to indicate the output tokens to use. If `target_mapping[k, i, j] = 1`, the i-th predict in batch k is
on the j-th token. Only used during pretraining for partial prediction or for sequential decoding
(generation).
input_mask (`torch.FloatTensor` of shape `batch_size, sequence_length`, *optional*):
Mask to avoid performing attention on padding token indices. Negative of `attention_mask`, i.e. with 0 for
real tokens and 1 for padding which is kept for compatibility with the original code base.
Mask values selected in `[0, 1]`:
- 1 for tokens that are **masked**,
- 0 for tokens that are **not masked**.
You can only uses one of `input_mask` and `attention_mask`.
use_mems (`bool`, *optional*):
Whether to use memory states to speed up sequential decoding. If set to `True`, the model will use the hidden
states from previous forward passes to compute attention, which can significantly improve performance for
sequential decoding tasks.
"""
return_dict = return_dict if return_dict is not None else self.config.use_return_dict
outputs = self.transformer(
input_ids,
attention_mask=attention_mask,
mems=mems,
perm_mask=perm_mask,
target_mapping=target_mapping,
token_type_ids=token_type_ids,
input_mask=input_mask,
head_mask=head_mask,
inputs_embeds=inputs_embeds,
use_mems=use_mems,
output_attentions=output_attentions,
output_hidden_states=output_hidden_states,
return_dict=return_dict,
**kwargs,
)
sequence_output = outputs[0]
logits = self.qa_outputs(sequence_output)
start_logits, end_logits = logits.split(1, dim=-1)
start_logits = start_logits.squeeze(-1).contiguous()
end_logits = end_logits.squeeze(-1).contiguous()
total_loss = None
if start_positions is not None and end_positions is not None:
# If we are on multi-GPU, split add a dimension
if len(start_positions.size()) > 1:
start_positions = start_positions.squeeze(-1)
if len(end_positions.size()) > 1:
end_positions = end_positions.squeeze(-1)
# sometimes the start/end positions are outside our model inputs, we ignore these terms
ignored_index = start_logits.size(1)
start_positions = start_positions.clamp(0, ignored_index)
end_positions = end_positions.clamp(0, ignored_index)
loss_fct = CrossEntropyLoss(ignore_index=ignored_index)
start_loss = loss_fct(start_logits, start_positions)
end_loss = loss_fct(end_logits, end_positions)
total_loss = (start_loss + end_loss) / 2
if not return_dict:
output = (start_logits, end_logits) + outputs[1:]
return ((total_loss,) + output) if total_loss is not None else output
return XLNetForQuestionAnsweringSimpleOutput(
loss=total_loss,
start_logits=start_logits,
end_logits=end_logits,
mems=outputs.mems,
hidden_states=outputs.hidden_states,
attentions=outputs.attentions,
)
@auto_docstring
class XLNetForQuestionAnswering(XLNetPreTrainedModel):
def __init__(self, config):
super().__init__(config)
self.start_n_top = config.start_n_top
self.end_n_top = config.end_n_top
self.transformer = XLNetModel(config)
self.start_logits = XLNetPoolerStartLogits(config)
self.end_logits = XLNetPoolerEndLogits(config)
self.answer_class = XLNetPoolerAnswerClass(config)
# Initialize weights and apply final processing
self.post_init()
@auto_docstring
def forward(
self,
input_ids: Optional[torch.Tensor] = None,
attention_mask: Optional[torch.Tensor] = None,
mems: Optional[torch.Tensor] = None,
perm_mask: Optional[torch.Tensor] = None,
target_mapping: Optional[torch.Tensor] = None,
token_type_ids: Optional[torch.Tensor] = None,
input_mask: Optional[torch.Tensor] = None,
head_mask: Optional[torch.Tensor] = None,
inputs_embeds: Optional[torch.Tensor] = None,
start_positions: Optional[torch.Tensor] = None,
end_positions: Optional[torch.Tensor] = None,
is_impossible: Optional[torch.Tensor] = None,
cls_index: Optional[torch.Tensor] = None,
p_mask: Optional[torch.Tensor] = None,
use_mems: Optional[bool] = None,
output_attentions: Optional[bool] = None,
output_hidden_states: Optional[bool] = None,
return_dict: Optional[bool] = None,
**kwargs, # delete when `use_cache` is removed in XLNetModel
) -> Union[tuple, XLNetForQuestionAnsweringOutput]:
r"""
mems (`list[torch.FloatTensor]` of length `config.n_layers`):
Contains pre-computed hidden-states (see `mems` output below) . Can be used to speed up sequential
decoding. The token ids which have their past given to this model should not be passed as `input_ids` as
they have already been computed.
`use_mems` has to be set to `True` to make use of `mems`.
perm_mask (`torch.FloatTensor` of shape `(batch_size, sequence_length, sequence_length)`, *optional*):
Mask to indicate the attention pattern for each input token with values selected in `[0, 1]`:
- if `perm_mask[k, i, j] = 0`, i attend to j in batch k;
- if `perm_mask[k, i, j] = 1`, i does not attend to j in batch k.
If not set, each token attends to all the others (full bidirectional attention). Only used during
pretraining (to define factorization order) or for sequential decoding (generation).
target_mapping (`torch.FloatTensor` of shape `(batch_size, num_predict, sequence_length)`, *optional*):
Mask to indicate the output tokens to use. If `target_mapping[k, i, j] = 1`, the i-th predict in batch k is
on the j-th token. Only used during pretraining for partial prediction or for sequential decoding
(generation).
input_mask (`torch.FloatTensor` of shape `batch_size, sequence_length`, *optional*):
Mask to avoid performing attention on padding token indices. Negative of `attention_mask`, i.e. with 0 for
real tokens and 1 for padding which is kept for compatibility with the original code base.
Mask values selected in `[0, 1]`:
- 1 for tokens that are **masked**,
- 0 for tokens that are **not masked**.
You can only uses one of `input_mask` and `attention_mask`.
is_impossible (`torch.LongTensor` of shape `(batch_size,)`, *optional*):
Labels whether a question has an answer or no answer (SQuAD 2.0)
cls_index (`torch.LongTensor` of shape `(batch_size,)`, *optional*):
Labels for position (index) of the classification token to use as input for computing plausibility of the
answer.
p_mask (`torch.FloatTensor` of shape `(batch_size, sequence_length)`, *optional*):
Optional mask of tokens which can't be in answers (e.g. [CLS], [PAD], ...). 1.0 means token should be
masked. 0.0 mean token is not masked.
use_mems (`bool`, *optional*):
Whether to use memory states to speed up sequential decoding. If set to `True`, the model will use the hidden
states from previous forward passes to compute attention, which can significantly improve performance for
sequential decoding tasks.
Example:
```python
>>> from transformers import AutoTokenizer, XLNetForQuestionAnswering
>>> import torch
>>> tokenizer = AutoTokenizer.from_pretrained("xlnet/xlnet-base-cased")
>>> model = XLNetForQuestionAnswering.from_pretrained("xlnet/xlnet-base-cased")
>>> input_ids = torch.tensor(tokenizer.encode("Hello, my dog is cute", add_special_tokens=True)).unsqueeze(
... 0
... ) # Batch size 1
>>> start_positions = torch.tensor([1])
>>> end_positions = torch.tensor([3])
>>> outputs = model(input_ids, start_positions=start_positions, end_positions=end_positions)
>>> loss = outputs.loss
```"""
return_dict = return_dict if return_dict is not None else self.config.use_return_dict
transformer_outputs = self.transformer(
input_ids,
attention_mask=attention_mask,
mems=mems,
perm_mask=perm_mask,
target_mapping=target_mapping,
token_type_ids=token_type_ids,
input_mask=input_mask,
head_mask=head_mask,
inputs_embeds=inputs_embeds,
use_mems=use_mems,
output_attentions=output_attentions,
output_hidden_states=output_hidden_states,
return_dict=return_dict,
**kwargs,
)
hidden_states = transformer_outputs[0]
start_logits = self.start_logits(hidden_states, p_mask=p_mask)
outputs = transformer_outputs[1:] # Keep mems, hidden states, attentions if there are in it
if start_positions is not None and end_positions is not None:
# If we are on multi-GPU, let's remove the dimension added by batch splitting
for x in (start_positions, end_positions, cls_index, is_impossible):
if x is not None and x.dim() > 1:
x.squeeze_(-1)
# during training, compute the end logits based on the ground truth of the start position
end_logits = self.end_logits(hidden_states, start_positions=start_positions, p_mask=p_mask)
loss_fct = CrossEntropyLoss()
start_loss = loss_fct(start_logits, start_positions)
end_loss = loss_fct(end_logits, end_positions)
total_loss = (start_loss + end_loss) / 2
if cls_index is not None and is_impossible is not None:
# Predict answerability from the representation of CLS and START
cls_logits = self.answer_class(hidden_states, start_positions=start_positions, cls_index=cls_index)
loss_fct_cls = nn.BCEWithLogitsLoss()
cls_loss = loss_fct_cls(cls_logits, is_impossible)
# note(zhiliny): by default multiply the loss by 0.5 so that the scale is comparable to start_loss and end_loss
total_loss += cls_loss * 0.5
if not return_dict:
return (total_loss,) + transformer_outputs[1:]
else:
return XLNetForQuestionAnsweringOutput(
loss=total_loss,
mems=transformer_outputs.mems,
hidden_states=transformer_outputs.hidden_states,
attentions=transformer_outputs.attentions,
)
else:
# during inference, compute the end logits based on beam search
bsz, slen, hsz = hidden_states.size()
start_log_probs = nn.functional.softmax(start_logits, dim=-1) # shape (bsz, slen)
start_top_log_probs, start_top_index = torch.topk(
start_log_probs, self.start_n_top, dim=-1
) # shape (bsz, start_n_top)
start_top_index_exp = start_top_index.unsqueeze(-1).expand(-1, -1, hsz) # shape (bsz, start_n_top, hsz)
start_states = torch.gather(hidden_states, -2, start_top_index_exp) # shape (bsz, start_n_top, hsz)
start_states = start_states.unsqueeze(1).expand(-1, slen, -1, -1) # shape (bsz, slen, start_n_top, hsz)
hidden_states_expanded = hidden_states.unsqueeze(2).expand_as(
start_states
) # shape (bsz, slen, start_n_top, hsz)
p_mask = p_mask.unsqueeze(-1) if p_mask is not None else None
end_logits = self.end_logits(hidden_states_expanded, start_states=start_states, p_mask=p_mask)
end_log_probs = nn.functional.softmax(end_logits, dim=1) # shape (bsz, slen, start_n_top)
end_top_log_probs, end_top_index = torch.topk(
end_log_probs, self.end_n_top, dim=1
) # shape (bsz, end_n_top, start_n_top)
end_top_log_probs = end_top_log_probs.view(-1, self.start_n_top * self.end_n_top)
end_top_index = end_top_index.view(-1, self.start_n_top * self.end_n_top)
start_states = torch.einsum(
"blh,bl->bh", hidden_states, start_log_probs
) # get the representation of START as weighted sum of hidden states
cls_logits = self.answer_class(
hidden_states, start_states=start_states, cls_index=cls_index
) # Shape (batch size,): one single `cls_logits` for each sample
if not return_dict:
outputs = (start_top_log_probs, start_top_index, end_top_log_probs, end_top_index, cls_logits)
return outputs + transformer_outputs[1:]
else:
return XLNetForQuestionAnsweringOutput(
start_top_log_probs=start_top_log_probs,
start_top_index=start_top_index,
end_top_log_probs=end_top_log_probs,
end_top_index=end_top_index,
cls_logits=cls_logits,
mems=transformer_outputs.mems,
hidden_states=transformer_outputs.hidden_states,
attentions=transformer_outputs.attentions,
)
__all__ = [
"XLNetForMultipleChoice",
"XLNetForQuestionAnswering",
"XLNetForQuestionAnsweringSimple",
"XLNetForSequenceClassification",
"XLNetForTokenClassification",
"XLNetLMHeadModel",
"XLNetModel",
"XLNetPreTrainedModel",
"load_tf_weights_in_xlnet",
]