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ColossalAI/examples/language/gpt/titans/model/embed.py

600 lines
25 KiB

import torch
import torch.nn.init as init
from torch import Tensor
from torch import distributed as dist
from torch import nn as nn
from torch.nn import functional as F
from torch.nn.parameter import Parameter
from colossalai.legacy.context import ParallelMode, seed
from colossalai.legacy.core import global_context as gpc
from colossalai.legacy.nn.layer.base_layer import ParallelLayer
from colossalai.legacy.nn.layer.parallel_1d._utils import gather_forward_split_backward, reduce_grad, reduce_input
from colossalai.legacy.nn.layer.parallel_1d.layers import Linear1D_Row
from colossalai.legacy.nn.layer.utils import divide
from colossalai.legacy.registry import LAYERS, LOSSES, MODELS
from colossalai.utils import get_current_device
class VocabParallelEmbedding(torch.nn.Module):
"""Language model embeddings.
Arguments:
hidden_size: hidden size
vocab_size: vocabulary size
max_sequence_length: maximum size of sequence. This
is used for positional embedding
embedding_dropout_prob: dropout probability for embeddings
init_method: weight initialization method
num_tokentypes: size of the token-type embeddings. 0 value
will ignore this embedding
"""
def __init__(self,
hidden_size,
vocab_size,
max_sequence_length,
embedding_dropout_prob,
num_tokentypes=0,
dtype=torch.float):
super(VocabParallelEmbedding, self).__init__()
self.hidden_size = hidden_size
self.num_tokentypes = num_tokentypes
# Word embeddings (parallel).
self.word_embeddings = VocabParallelEmbedding1D(vocab_size, self.hidden_size, dtype=dtype)
self._word_embeddings_key = 'word_embeddings'
# Position embedding (serial).
self.position_embeddings = torch.nn.Embedding(max_sequence_length, self.hidden_size, dtype=dtype)
self._position_embeddings_key = 'position_embeddings'
# Initialize the position embeddings.
# self.init_method(self.position_embeddings.weight)
# Token type embedding.
# Add this as an optional field that can be added through
# method call so we can load a pretrain model without
# token types and add them as needed.
self._tokentype_embeddings_key = 'tokentype_embeddings'
if self.num_tokentypes > 0:
self.tokentype_embeddings = torch.nn.Embedding(self.num_tokentypes, self.hidden_size, dtype=dtype)
# Initialize the token-type embeddings.
# self.init_method(self.tokentype_embeddings.weight)
else:
self.tokentype_embeddings = None
# Embeddings dropout
self.embedding_dropout = torch.nn.Dropout(embedding_dropout_prob)
def zero_parameters(self):
"""Zero out all parameters in embedding."""
self.word_embeddings.weight.data.fill_(0)
self.word_embeddings.weight.shared = True
self.position_embeddings.weight.data.fill_(0)
self.position_embeddings.weight.shared = True
if self.num_tokentypes > 0:
self.tokentype_embeddings.weight.data.fill_(0)
self.tokentype_embeddings.weight.shared = True
def add_tokentype_embeddings(self, num_tokentypes):
"""Add token-type embedding. This function is provided so we can add
token-type embeddings in case the pretrained model does not have it.
This allows us to load the model normally and then add this embedding.
"""
if self.tokentype_embeddings is not None:
raise Exception('tokentype embeddings is already initialized')
if torch.distributed.get_rank() == 0:
print('adding embedding for {} tokentypes'.format(num_tokentypes), flush=True)
self.num_tokentypes = num_tokentypes
self.tokentype_embeddings = torch.nn.Embedding(num_tokentypes, self.hidden_size)
# Initialize the token-type embeddings.
# self.init_method(self.tokentype_embeddings.weight)
def forward(self, input_ids, position_ids=None, tokentype_ids=None):
# Embeddings.
if input_ids is not None:
input_shape = input_ids.size()
input_ids = input_ids.view(-1, input_shape[-1])
words_embeddings = self.word_embeddings(input_ids)
if position_ids is not None:
position_ids = position_ids.view(-1, input_shape[-1])
if position_ids is None:
position_ids = torch.arange(0, input_shape[-1] + 0, dtype=torch.long, device=get_current_device())
position_ids = position_ids.unsqueeze(0).view(-1, input_shape[-1])
position_embeddings = self.position_embeddings(position_ids)
embeddings = words_embeddings + position_embeddings
# Dropout.
with seed(ParallelMode.TENSOR):
embeddings = self.embedding_dropout(embeddings)
return embeddings
def state_dict_for_save_checkpoint(self, destination=None, prefix='', keep_vars=False):
"""For easy load."""
state_dict_ = {}
state_dict_[self._word_embeddings_key] \
= self.word_embeddings.state_dict(destination, prefix, keep_vars)
state_dict_[self._position_embeddings_key] \
= self.position_embeddings.state_dict(
destination, prefix, keep_vars)
if self.num_tokentypes > 0:
state_dict_[self._tokentype_embeddings_key] \
= self.tokentype_embeddings.state_dict(
destination, prefix, keep_vars)
return state_dict_
def load_state_dict(self, state_dict, strict=True):
"""Customized load."""
# Word embedding.
if self._word_embeddings_key in state_dict:
state_dict_ = state_dict[self._word_embeddings_key]
else:
# for backward compatibility.
state_dict_ = {}
for key in state_dict.keys():
if 'word_embeddings' in key:
state_dict_[key.split('word_embeddings.')[1]] \
= state_dict[key]
self.word_embeddings.load_state_dict(state_dict_, strict=strict)
# Position embedding.
if self._position_embeddings_key in state_dict:
state_dict_ = state_dict[self._position_embeddings_key]
else:
# for backward compatibility.
state_dict_ = {}
for key in state_dict.keys():
if 'position_embeddings' in key:
state_dict_[key.split('position_embeddings.')[1]] \
= state_dict[key]
self.position_embeddings.load_state_dict(state_dict_, strict=strict)
# Tokentype embedding.
if self.num_tokentypes > 0:
state_dict_ = {}
if self._tokentype_embeddings_key in state_dict:
state_dict_ = state_dict[self._tokentype_embeddings_key]
else:
# for backward compatibility.
for key in state_dict.keys():
if 'tokentype_embeddings' in key:
state_dict_[key.split('tokentype_embeddings.')[1]] \
= state_dict[key]
if len(state_dict_.keys()) > 0:
self.tokentype_embeddings.load_state_dict(state_dict_, strict=strict)
else:
print('***WARNING*** expected tokentype embeddings in the '
'checkpoint but could not find it',
flush=True)
class VocabParallelEmbedding1D(torch.nn.Module):
"""Embedding parallelized in the vocabulary dimension.
This is mainly adapted from torch.nn.Embedding and all the default
values are kept.
Arguments:
num_embeddings: vocabulary size.
embedding_dim: size of hidden state.
init_method: method to initialize weights.
"""
def __init__(self, num_embeddings, embedding_dim, dtype=None, init_method=None):
super(VocabParallelEmbedding1D, self).__init__()
# Keep the input dimensions.
self.num_embeddings = num_embeddings
self.embedding_dim = embedding_dim
# Set the details for compatibility.
self.padding_idx = None
self.max_norm = None
self.norm_type = 2.
self.scale_grad_by_freq = False
self.sparse = False
self._weight = None
self.tensor_model_parallel_size = gpc.tensor_parallel_size
# Divide the weight matrix along the vocabulary dimension.
self.vocab_start_index, self.vocab_end_index = \
VocabUtility.vocab_range_from_global_vocab_size(
self.num_embeddings, gpc.get_local_rank(ParallelMode.PARALLEL_1D),
self.tensor_model_parallel_size)
self.num_embeddings_per_partition = self.vocab_end_index - \
self.vocab_start_index
# Allocate weights and initialize.
factory_kwargs = {'device': get_current_device(), 'dtype': dtype}
self.weight = Parameter(torch.empty(self.num_embeddings_per_partition, self.embedding_dim, **factory_kwargs))
init.uniform_(self.weight, -1, 1)
def forward(self, input_):
if self.tensor_model_parallel_size > 1:
# Build the mask.
input_mask = (input_ < self.vocab_start_index) | \
(input_ >= self.vocab_end_index)
# Mask the input.
masked_input = input_.clone() - self.vocab_start_index
masked_input[input_mask] = 0
else:
masked_input = input_
# Get the embeddings.
output_parallel = F.embedding(masked_input, self.weight, self.padding_idx, self.max_norm, self.norm_type,
self.scale_grad_by_freq, self.sparse)
# Mask the output embedding.
if self.tensor_model_parallel_size > 1:
output_parallel[input_mask, :] = 0.0
# Reduce across all the model parallel GPUs.
output = output = reduce_input(output_parallel, ParallelMode.PARALLEL_1D)
return output
@LOSSES.register_module
class vocab_parallel_cross_entropy(nn.Module):
def __init__(self):
super().__init__()
def forward(self, vocab_parallel_logits, target):
"""Helper function for the cross entropy."""
vocab_parallel_logits = vocab_parallel_logits[..., :-1, :].contiguous()
target = target[..., 1:].contiguous()
return _VocabParallelCrossEntropy.apply(vocab_parallel_logits.view(-1, vocab_parallel_logits.size(-1)),
target.view(-1))
class _VocabParallelCrossEntropy(torch.autograd.Function):
@staticmethod
def forward(ctx, vocab_parallel_logits, target):
# Maximum value along vocab dimension across all GPUs.
logits_max = torch.max(vocab_parallel_logits, dim=-1)[0]
torch.distributed.all_reduce(logits_max,
op=torch.distributed.ReduceOp.MAX,
group=gpc.get_group(ParallelMode.PARALLEL_1D))
# Subtract the maximum value.
vocab_parallel_logits.sub_(logits_max.unsqueeze(dim=-1))
# Get the partition's vocab indices
get_vocab_range = VocabUtility.vocab_range_from_per_partition_vocab_size
partition_vocab_size = vocab_parallel_logits.size()[-1]
rank = gpc.get_local_rank(ParallelMode.PARALLEL_1D)
world_size = gpc.tensor_parallel_size
vocab_start_index, vocab_end_index = get_vocab_range(partition_vocab_size, rank, world_size)
# Create a mask of valid vocab ids (1 means it needs to be masked).
target_mask = (target < vocab_start_index) | (target >= vocab_end_index)
masked_target = target.clone() - vocab_start_index
masked_target[target_mask] = 0
# Get predicted-logits = logits[target].
# For Simplicity, we convert logits to a 2-D tensor with size
# [*, partition-vocab-size] and target to a 1-D tensor of size [*].
logits_2d = vocab_parallel_logits.view(-1, partition_vocab_size)
masked_target_1d = masked_target.view(-1)
arange_1d = torch.arange(start=0, end=logits_2d.size()[0], device=logits_2d.device)
predicted_logits_1d = logits_2d[arange_1d, masked_target_1d]
predicted_logits_1d = predicted_logits_1d.clone().contiguous()
predicted_logits = predicted_logits_1d.view_as(target)
predicted_logits[target_mask] = 0.0
# All reduce is needed to get the chunks from other GPUs.
torch.distributed.all_reduce(predicted_logits,
op=torch.distributed.ReduceOp.SUM,
group=gpc.get_group(ParallelMode.PARALLEL_1D))
# Sum of exponential of logits along vocab dimension across all GPUs.
exp_logits = vocab_parallel_logits
torch.exp(vocab_parallel_logits, out=exp_logits)
sum_exp_logits = exp_logits.sum(dim=-1)
torch.distributed.all_reduce(sum_exp_logits,
op=torch.distributed.ReduceOp.SUM,
group=gpc.get_group(ParallelMode.PARALLEL_1D))
# Loss = log(sum(exp(logits))) - predicted-logit.
loss = torch.log(sum_exp_logits) - predicted_logits
loss = loss.mean()
# Store softmax, target-mask and masked-target for backward pass.
exp_logits.div_(sum_exp_logits.unsqueeze(dim=-1))
ctx.save_for_backward(exp_logits, target_mask, masked_target_1d)
return loss
@staticmethod
def backward(ctx, grad_output):
# Retrieve tensors from the forward path.
softmax, target_mask, masked_target_1d = ctx.saved_tensors
# All the inputs have softmax as their gradient.
grad_input = softmax
# For simplicity, work with the 2D gradient.
partition_vocab_size = softmax.size()[-1]
grad_2d = grad_input.view(-1, partition_vocab_size)
# Add the gradient from matching classes.
arange_1d = torch.arange(start=0, end=grad_2d.size()[0], device=grad_2d.device)
grad_2d[arange_1d, masked_target_1d] -= (1.0 - target_mask.view(-1).float())
# Finally elementwise multiplication with the output gradients.
grad_input.mul_(grad_output.unsqueeze(dim=-1))
return grad_input, None
class VocabUtility:
"""Split the vocabulary into `world_size` chunks amd return the
first and last index of the vocabulary belonging to the `rank`
partition: Note that indices in [fist, last)"""
@staticmethod
def vocab_range_from_per_partition_vocab_size(per_partition_vocab_size, rank, world_size):
index_f = rank * per_partition_vocab_size
index_l = index_f + per_partition_vocab_size
return index_f, index_l
@staticmethod
def vocab_range_from_global_vocab_size(global_vocab_size, rank, world_size):
per_partition_vocab_size = divide(global_vocab_size, world_size)
return VocabUtility.vocab_range_from_per_partition_vocab_size(per_partition_vocab_size, rank, world_size)
class VocabParallelGPTLMHead1D(ParallelLayer):
"""
Language model head that shares the same parameters with the embedding matrix.
"""
def __init__(self, embed=None, vocab_size=None, dtype=None, embed_dim=None):
super().__init__()
if embed is not None:
self.head = embed
else:
self.head = VocabParallelEmbedding1D(vocab_size, embed_dim, dtype=dtype)
def forward(self, x: Tensor) -> Tensor:
x = reduce_grad(x, ParallelMode.PARALLEL_1D)
x = F.linear(x, self.head.weight)
return x
###################################
class HiddenParallelEmbedding(torch.nn.Module):
"""Language model embeddings.
Arguments:
hidden_size: hidden size
vocab_size: vocabulary size
max_sequence_length: maximum size of sequence. This
is used for positional embedding
embedding_dropout_prob: dropout probability for embeddings
init_method: weight initialization method
num_tokentypes: size of the token-type embeddings. 0 value
will ignore this embedding
"""
def __init__(
self,
hidden_size,
vocab_size,
max_sequence_length,
embedding_dropout_prob,
dtype=torch.float,
padding_idx: int = 0,
num_tokentypes=0,
):
super(HiddenParallelEmbedding, self).__init__()
self.hidden_size = hidden_size
self.num_tokentypes = num_tokentypes
# Word embeddings (parallel).
self.word_embeddings = HiddenParallelEmbedding1D(vocab_size, hidden_size, dtype, padding_idx)
self._word_embeddings_key = 'word_embeddings'
# Position embedding (serial).
self.position_embeddings = torch.nn.Embedding(max_sequence_length, self.hidden_size)
self._position_embeddings_key = 'position_embeddings'
# Initialize the position embeddings.
# self.init_method(self.position_embeddings.weight)
# Token type embedding.
# Add this as an optional field that can be added through
# method call so we can load a pretrain model without
# token types and add them as needed.
self._tokentype_embeddings_key = 'tokentype_embeddings'
if self.num_tokentypes > 0:
self.tokentype_embeddings = torch.nn.Embedding(self.num_tokentypes, self.hidden_size)
# Initialize the token-type embeddings.
# self.init_method(self.tokentype_embeddings.weight)
else:
self.tokentype_embeddings = None
# Embeddings dropout
self.embedding_dropout = torch.nn.Dropout(embedding_dropout_prob)
def zero_parameters(self):
"""Zero out all parameters in embedding."""
self.word_embeddings.weight.data.fill_(0)
self.word_embeddings.weight.shared = True
self.position_embeddings.weight.data.fill_(0)
self.position_embeddings.weight.shared = True
if self.num_tokentypes > 0:
self.tokentype_embeddings.weight.data.fill_(0)
self.tokentype_embeddings.weight.shared = True
def add_tokentype_embeddings(self, num_tokentypes):
"""Add token-type embedding. This function is provided so we can add
token-type embeddings in case the pretrained model does not have it.
This allows us to load the model normally and then add this embedding.
"""
if self.tokentype_embeddings is not None:
raise Exception('tokentype embeddings is already initialized')
if torch.distributed.get_rank() == 0:
print('adding embedding for {} tokentypes'.format(num_tokentypes), flush=True)
self.num_tokentypes = num_tokentypes
self.tokentype_embeddings = torch.nn.Embedding(num_tokentypes, self.hidden_size)
# Initialize the token-type embeddings.
# self.init_method(self.tokentype_embeddings.weight)
def forward(self, input_ids, position_ids=None, tokentype_ids=None):
if input_ids is not None:
input_shape = input_ids.size()
input_ids = input_ids.view(-1, input_shape[-1])
words_embeddings = self.word_embeddings(input_ids)
if position_ids is not None:
position_ids = position_ids.view(-1, input_shape[-1])
if position_ids is None:
position_ids = torch.arange(0, input_shape[-1] + 0, dtype=torch.long, device=get_current_device())
position_ids = position_ids.unsqueeze(0).view(-1, input_shape[-1])
position_embeddings = self.position_embeddings(position_ids)
embeddings = words_embeddings + position_embeddings
# Dropout.
with seed(ParallelMode.TENSOR):
embeddings = self.embedding_dropout(embeddings)
return embeddings
def state_dict_for_save_checkpoint(self, destination=None, prefix='', keep_vars=False):
"""For easy load."""
state_dict_ = {}
state_dict_[self._word_embeddings_key] \
= self.word_embeddings.state_dict(destination, prefix, keep_vars)
state_dict_[self._position_embeddings_key] \
= self.position_embeddings.state_dict(
destination, prefix, keep_vars)
if self.num_tokentypes > 0:
state_dict_[self._tokentype_embeddings_key] \
= self.tokentype_embeddings.state_dict(
destination, prefix, keep_vars)
return state_dict_
def load_state_dict(self, state_dict, strict=True):
"""Customized load."""
# Word embedding.
if self._word_embeddings_key in state_dict:
state_dict_ = state_dict[self._word_embeddings_key]
else:
# for backward compatibility.
state_dict_ = {}
for key in state_dict.keys():
if 'word_embeddings' in key:
state_dict_[key.split('word_embeddings.')[1]] \
= state_dict[key]
self.word_embeddings.load_state_dict(state_dict_, strict=strict)
# Position embedding.
if self._position_embeddings_key in state_dict:
state_dict_ = state_dict[self._position_embeddings_key]
else:
# for backward compatibility.
state_dict_ = {}
for key in state_dict.keys():
if 'position_embeddings' in key:
state_dict_[key.split('position_embeddings.')[1]] \
= state_dict[key]
self.position_embeddings.load_state_dict(state_dict_, strict=strict)
# Tokentype embedding.
if self.num_tokentypes > 0:
state_dict_ = {}
if self._tokentype_embeddings_key in state_dict:
state_dict_ = state_dict[self._tokentype_embeddings_key]
else:
# for backward compatibility.
for key in state_dict.keys():
if 'tokentype_embeddings' in key:
state_dict_[key.split('tokentype_embeddings.')[1]] \
= state_dict[key]
if len(state_dict_.keys()) > 0:
self.tokentype_embeddings.load_state_dict(state_dict_, strict=strict)
else:
print('***WARNING*** expected tokentype embeddings in the '
'checkpoint but could not find it',
flush=True)
class HiddenParallelEmbedding1D(torch.nn.Module):
"""Embedding parallelized in the vocabulary dimension.
This is mainly adapted from torch.nn.Embedding and all the default
values are kept.
Arguments:
num_embeddings: vocabulary size.
embedding_dim: size of hidden state.
init_method: method to initialize weights.
"""
def __init__(self, num_embeddings, embedding_dim, dtype=torch.float, padding_idx: int = None, init_method=None):
super(HiddenParallelEmbedding1D, self).__init__()
# Keep the input dimensions.
self.num_embeddings = num_embeddings
self.embedding_dim = embedding_dim
embed_dim_per_partition = divide(embedding_dim, gpc.tensor_parallel_size)
# Set the details for compatibility.
self.padding_idx = padding_idx
self.max_norm = None
self.norm_type = 2.
self.scale_grad_by_freq = False
self.sparse = False
self._weight = None
# Allocate weights and initialize.
factory_kwargs = {'device': get_current_device(), 'dtype': dtype}
self.weight = Parameter(torch.empty(num_embeddings, embed_dim_per_partition, **factory_kwargs))
init.uniform_(self.weight, -1, 1)
def forward(self, input_):
# Get the embeddings.
output_parallel = F.embedding(input_, self.weight, self.padding_idx, self.max_norm, self.norm_type,
self.scale_grad_by_freq, self.sparse)
# Reduce across all the model parallel GPUs.
output = gather_forward_split_backward(output_parallel, ParallelMode.PARALLEL_1D, dim=-1)
return output
@LAYERS.register_module
class HiddenParallelGPTLMHead1D(ParallelLayer):
"""
Language model head that shares the same parameters with the embedding matrix.
"""
def __init__(
self,
embed=None,
embed_dim=None,
vocab_size=None,
dtype=None,
):
super().__init__()
if embed is not None:
self.head = embed
self.synced_embed = True
else:
# self.embedding = HiddenParallelEmbedding1D(vocab_size, hidden_size, dtype, padding_idx)
# (hidden_size/q, vocab_size)
self.synced_embed = False
self.head = Linear1D_Row(in_features=embed_dim,
out_features=vocab_size,
bias=False,
dtype=dtype,
parallel_input=False)
def forward(self, x: Tensor) -> Tensor:
if self.synced_embed:
x = F.linear(x, self.head.weight)
else:
x = self.head(x)
return x