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layers.py
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# coding=utf-8
# Copyright (c) 2020, 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.
# Parts of the code here are adapted from PyTorch
# repo: https://github.com/pytorch/pytorch
import math
import torch
import torch.nn.functional as F
import torch.nn.init as init
from torch.nn.parameter import Parameter
from .initialize import get_tensor_model_parallel_rank
from .initialize import get_tensor_model_parallel_world_size
from .initialize import get_tensor_model_parallel_group
from .mappings import copy_to_tensor_model_parallel_region
from .mappings import gather_from_tensor_model_parallel_region
from .mappings import reduce_from_tensor_model_parallel_region
from .mappings import scatter_to_tensor_model_parallel_region
from .random import get_cuda_rng_tracker
from .utils import divide
from .utils import split_tensor_along_last_dim
from .utils import VocabUtility
from megatron import get_args
_MODEL_PARALLEL_ATTRIBUTE_DEFAULTS = {'tensor_model_parallel': False,
'partition_dim': -1,
'partition_stride': 1}
def param_is_not_tensor_parallel_duplicate(param):
return (hasattr(param, 'tensor_model_parallel') and
param.tensor_model_parallel) or (
get_tensor_model_parallel_rank() == 0)
def set_tensor_model_parallel_attributes(tensor, is_parallel, dim, stride):
# Make sure the attributes are not set.
for attribute in _MODEL_PARALLEL_ATTRIBUTE_DEFAULTS:
assert not hasattr(tensor, attribute)
# Set the attributes.
setattr(tensor, 'tensor_model_parallel', is_parallel)
setattr(tensor, 'partition_dim', dim)
setattr(tensor, 'partition_stride', stride)
def set_defaults_if_not_set_tensor_model_parallel_attributes(tensor):
def maybe_set(attribute, value):
if not hasattr(tensor, attribute):
setattr(tensor, attribute, value)
for attribute in _MODEL_PARALLEL_ATTRIBUTE_DEFAULTS:
maybe_set(attribute, _MODEL_PARALLEL_ATTRIBUTE_DEFAULTS[attribute])
def copy_tensor_model_parallel_attributes(destination_tensor, source_tensor):
def maybe_copy(attribute):
if hasattr(source_tensor, attribute):
setattr(destination_tensor, attribute,
getattr(source_tensor, attribute))
for attribute in _MODEL_PARALLEL_ATTRIBUTE_DEFAULTS:
maybe_copy(attribute)
def _initialize_affine_weight_gpu(weight, init_method,
partition_dim, stride=1):
"""Initialize affine weight for model parallel on GPU."""
set_tensor_model_parallel_attributes(tensor=weight,
is_parallel=True,
dim=partition_dim,
stride=stride)
with get_cuda_rng_tracker().fork():
init_method(weight)
def _initialize_affine_weight_cpu(weight, output_size, input_size,
per_partition_size, partition_dim,
init_method, stride=1,
return_master_weight=False):
"""Initialize affine weight for model parallel.
Build the master weight on all processes and scatter
the relevant chunk."""
set_tensor_model_parallel_attributes(tensor=weight,
is_parallel=True,
dim=partition_dim,
stride=stride)
# Initialize master weight
master_weight = torch.empty(output_size, input_size,
dtype=torch.float,
requires_grad=False)
init_method(master_weight)
args = get_args()
master_weight = master_weight.to(dtype=args.params_dtype)
# Split and copy
per_partition_per_stride_size = divide(per_partition_size, stride)
weight_list = torch.split(master_weight, per_partition_per_stride_size,
dim=partition_dim)
rank = get_tensor_model_parallel_rank()
world_size = get_tensor_model_parallel_world_size()
my_weight_list = weight_list[rank::world_size]
with torch.no_grad():
torch.cat(my_weight_list, dim=partition_dim, out=weight)
if return_master_weight:
return master_weight
return None
class VocabParallelEmbedding(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,
init_method=init.xavier_normal_):
super(VocabParallelEmbedding, self).__init__()
# Keep the input dimensions.
self.num_embeddings = num_embeddings
self.embedding_dim = embedding_dim
# Set the detauls 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 = get_tensor_model_parallel_world_size()
# Divide the weight matrix along the vocaburaly dimension.
self.vocab_start_index, self.vocab_end_index = \
VocabUtility.vocab_range_from_global_vocab_size(
self.num_embeddings, get_tensor_model_parallel_rank(),
self.tensor_model_parallel_size)
self.num_embeddings_per_partition = self.vocab_end_index - \
self.vocab_start_index
# Allocate weights and initialize.
args = get_args()
if args.use_cpu_initialization:
self.weight = Parameter(torch.empty(
self.num_embeddings_per_partition, self.embedding_dim,
dtype=args.params_dtype))
_initialize_affine_weight_cpu(
self.weight, self.num_embeddings, self.embedding_dim,
self.num_embeddings_per_partition, 0, init_method)
else:
self.weight = Parameter(torch.empty(
self.num_embeddings_per_partition, self.embedding_dim,
device=torch.cuda.current_device(), dtype=args.params_dtype))
_initialize_affine_weight_gpu(self.weight, init_method,
partition_dim=0, stride=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 = reduce_from_tensor_model_parallel_region(output_parallel)
return output
class ColumnParallelLinearWithAsyncAllreduce(torch.autograd.Function):
"""
Column-parallel linear layer execution with asynchronous all-reduce
execution in backprop.
"""
@staticmethod
def forward(ctx, input, weight, bias):
ctx.save_for_backward(input, weight)
ctx.use_bias = bias is not None
output = torch.matmul(input, weight.t())
if bias is not None:
output = output + bias
return output
@staticmethod
def backward(ctx, grad_output):
input, weight = ctx.saved_tensors
use_bias = ctx.use_bias
grad_input = grad_output.matmul(weight)
# Asyncronous all-reduce
handle = torch.distributed.all_reduce(
grad_input, group=get_tensor_model_parallel_group(), async_op=True)
# Delay the start of weight gradient computation shortly (3us) to have
# all-reduce scheduled first and have GPU resources allocated
_ = torch.empty(1, device=grad_output.device) + 1
grad_weight = grad_output.t().matmul(input)
grad_bias = grad_output.sum(dim=0) if use_bias else None
handle.wait()
return grad_input, grad_weight, grad_bias
class ColumnParallelLinear(torch.nn.Module):
"""Linear layer with column parallelism.
The linear layer is defined as Y = XA + b. A is parallelized along
its second dimension as A = [A_1, ..., A_p].
Arguments:
input_size: first dimension of matrix A.
output_size: second dimension of matrix A.
bias: If true, add bias
gather_output: If true, call all-gether on output and make Y avaiable
to all GPUs, otherwise, every GPU will have its output
which is Y_i = XA_i
init_method: method to initialize weights. Note that bias is always set
to zero.
stride: For the strided linear layers.
keep_master_weight_for_test: This was added for testing and should be
set to False. It returns the master weights
used for initialization.
skip_bias_add: This was added to enable performance optimations where bias
can be fused with other elementwise operations. we skip
adding bias but instead return it.
"""
def __init__(self, input_size, output_size, bias=True, gather_output=True,
init_method=init.xavier_normal_, stride=1,
keep_master_weight_for_test=False,
skip_bias_add=False):
super(ColumnParallelLinear, self).__init__()
# Keep input parameters
self.input_size = input_size
self.output_size = output_size
self.gather_output = gather_output
# Divide the weight matrix along the last dimension.
world_size = get_tensor_model_parallel_world_size()
self.output_size_per_partition = divide(output_size, world_size)
self.skip_bias_add = skip_bias_add
# Parameters.
# Note: torch.nn.functional.linear performs XA^T + b and as a result
# we allocate the transpose.
# Initialize weight.
args = get_args()
if args.use_cpu_initialization:
self.weight = Parameter(torch.empty(self.output_size_per_partition,
self.input_size,
dtype=args.params_dtype))
self.master_weight = _initialize_affine_weight_cpu(
self.weight, self.output_size, self.input_size,
self.output_size_per_partition, 0, init_method,
stride=stride, return_master_weight=keep_master_weight_for_test)
else:
self.weight = Parameter(torch.empty(
self.output_size_per_partition, self.input_size,
device=torch.cuda.current_device(), dtype=args.params_dtype))
_initialize_affine_weight_gpu(self.weight, init_method,
partition_dim=0, stride=stride)
if bias:
if args.use_cpu_initialization:
self.bias = Parameter(torch.empty(
self.output_size_per_partition, dtype=args.params_dtype))
else:
self.bias = Parameter(torch.empty(
self.output_size_per_partition,
device=torch.cuda.current_device(),
dtype=args.params_dtype))
set_tensor_model_parallel_attributes(self.bias, True, 0, stride)
# Always initialize bias to zero.
with torch.no_grad():
self.bias.zero_()
else:
self.register_parameter('bias', None)
self.async_tensor_model_parallel_allreduce = (
not args.no_async_tensor_model_parallel_allreduce and
world_size > 1)
def forward(self, input_):
bias = self.bias if not self.skip_bias_add else None
if self.async_tensor_model_parallel_allreduce:
input_shape = input_.shape
input_ = input_.view(input_shape[0] * input_shape[1],input_shape[2])
# Maxtrix multiply with asynchronouse all-reduce execution
output_parallel = ColumnParallelLinearWithAsyncAllreduce.apply(
input_, self.weight, bias)
output_parallel = output_parallel.view(
input_shape[0], input_shape[1], output_parallel.shape[1])
else:
# Set up backprop all-reduce.
input_parallel = copy_to_tensor_model_parallel_region(input_)
# Matrix multiply.
output_parallel = F.linear(input_parallel, self.weight, bias)
if self.gather_output:
# All-gather across the partitions.
output = gather_from_tensor_model_parallel_region(output_parallel)
else:
output = output_parallel
output_bias = self.bias if self.skip_bias_add else None
return output, output_bias
class RowParallelLinear(torch.nn.Module):
"""Linear layer with row parallelism.
The linear layer is defined as Y = XA + b. A is parallelized along
its first dimension and X along its second dimension as:
- -
| A_1 |
| . |
A = | . | X = [X_1, ..., X_p]
| . |
| A_p |
- -
Arguments:
input_size: first dimension of matrix A.
output_size: second dimension of matrix A.
bias: If true, add bias. Note that bias is not parallelized.
input_is_parallel: If true, we assume that the input is already
split across the GPUs and we do not split
again.
init_method: method to initialize weights. Note that bias is always set
to zero.
stride: For the strided linear layers.
keep_master_weight_for_test: This was added for testing and should be
set to False. It returns the master weights
used for initialization.
skip_bias_add: This was added to enable performance optimization where bias
can be fused with other elementwise operations. We skip
adding bias but instead return it.
"""
def __init__(self, input_size, output_size, bias=True,
input_is_parallel=False,
init_method=init.xavier_normal_, stride=1,
keep_master_weight_for_test=False,
skip_bias_add=False):
super(RowParallelLinear, self).__init__()
# Keep input parameters
self.input_size = input_size
self.output_size = output_size
self.input_is_parallel = input_is_parallel
# Divide the weight matrix along the last dimension.
world_size = get_tensor_model_parallel_world_size()
self.input_size_per_partition = divide(input_size, world_size)
self.skip_bias_add = skip_bias_add
# Parameters.
# Note: torch.nn.functional.linear performs XA^T + b and as a result
# we allocate the transpose.
# Initialize weight.
args = get_args()
if args.use_cpu_initialization:
self.weight = Parameter(torch.empty(self.output_size,
self.input_size_per_partition,
dtype=args.params_dtype))
self.master_weight = _initialize_affine_weight_cpu(
self.weight, self.output_size, self.input_size,
self.input_size_per_partition, 1, init_method,
stride=stride, return_master_weight=keep_master_weight_for_test)
else:
self.weight = Parameter(torch.empty(
self.output_size, self.input_size_per_partition,
device=torch.cuda.current_device(), dtype=args.params_dtype))
_initialize_affine_weight_gpu(self.weight, init_method,
partition_dim=1, stride=stride)
if bias:
if args.use_cpu_initialization:
self.bias = Parameter(torch.empty(self.output_size,
dtype=args.params_dtype))
else:
self.bias = Parameter(torch.empty(
self.output_size, device=torch.cuda.current_device(),
dtype=args.params_dtype))
# Always initialize bias to zero.
with torch.no_grad():
self.bias.zero_()
else:
self.register_parameter('bias', None)
def forward(self, input_):
# Set up backprop all-reduce.
if self.input_is_parallel:
input_parallel = input_
else:
input_parallel = scatter_to_tensor_model_parallel_region(input_)
# Matrix multiply.
output_parallel = F.linear(input_parallel, self.weight)
# All-reduce across all the partitions.
output_ = reduce_from_tensor_model_parallel_region(output_parallel)
if not self.skip_bias_add:
output = output_ + self.bias if self.bias is not None else output_
output_bias = None
else:
output = output_
output_bias = self.bias
return output, output_bias