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# Copyright 2022 Xiaomi Corp. (authors: Daniel Povey, Zengwei Yao)
#
# See ../../../../LICENSE for clarification regarding multiple authors
#
# 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.
import collections
import random
from itertools import repeat
from typing import Optional, Tuple
import torch
import torch.backends.cudnn.rnn as rnn
import torch.nn as nn
from torch import _VF, Tensor
from icefall.utils import is_jit_tracing
def _ntuple(n):
def parse(x):
if isinstance(x, collections.Iterable):
return x
return tuple(repeat(x, n))
return parse
_single = _ntuple(1)
_pair = _ntuple(2)
class ActivationBalancerFunction(torch.autograd.Function):
@staticmethod
def forward(
ctx,
x: Tensor,
channel_dim: int,
min_positive: float, # e.g. 0.05
max_positive: float, # e.g. 0.95
max_factor: float, # e.g. 0.01
min_abs: float, # e.g. 0.2
max_abs: float, # e.g. 100.0
) -> Tensor:
if x.requires_grad:
if channel_dim < 0:
channel_dim += x.ndim
# sum_dims = [d for d in range(x.ndim) if d != channel_dim]
# The above line is not torch scriptable for torch 1.6.0
# torch.jit.frontend.NotSupportedError: comprehension ifs not supported yet: # noqa
sum_dims = []
for d in range(x.ndim):
if d != channel_dim:
sum_dims.append(d)
xgt0 = x > 0
proportion_positive = torch.mean(
xgt0.to(x.dtype), dim=sum_dims, keepdim=True
)
factor1 = (
(min_positive - proportion_positive).relu()
* (max_factor / min_positive)
if min_positive != 0.0
else 0.0
)
factor2 = (
(proportion_positive - max_positive).relu()
* (max_factor / (max_positive - 1.0))
if max_positive != 1.0
else 0.0
)
factor = factor1 + factor2
if isinstance(factor, float):
factor = torch.zeros_like(proportion_positive)
mean_abs = torch.mean(x.abs(), dim=sum_dims, keepdim=True)
below_threshold = mean_abs < min_abs
above_threshold = mean_abs > max_abs
ctx.save_for_backward(factor, xgt0, below_threshold, above_threshold)
ctx.max_factor = max_factor
ctx.sum_dims = sum_dims
return x
@staticmethod
def backward(
ctx, x_grad: Tensor
) -> Tuple[Tensor, None, None, None, None, None, None]:
factor, xgt0, below_threshold, above_threshold = ctx.saved_tensors
dtype = x_grad.dtype
scale_factor = (
(below_threshold.to(dtype) - above_threshold.to(dtype))
* (xgt0.to(dtype) - 0.5)
* (ctx.max_factor * 2.0)
)
neg_delta_grad = x_grad.abs() * (factor + scale_factor)
return x_grad - neg_delta_grad, None, None, None, None, None, None
class GradientFilterFunction(torch.autograd.Function):
@staticmethod
def forward(
ctx,
x: Tensor,
batch_dim: int, # e.g., 1
threshold: float, # e.g., 10.0
*params: Tensor, # module parameters
) -> Tuple[Tensor, ...]:
if x.requires_grad:
if batch_dim < 0:
batch_dim += x.ndim
ctx.batch_dim = batch_dim
ctx.threshold = threshold
return (x,) + params
@staticmethod
def backward(
ctx,
x_grad: Tensor,
*param_grads: Tensor,
) -> Tuple[Tensor, ...]:
eps = 1.0e-20
dim = ctx.batch_dim
norm_dims = [d for d in range(x_grad.ndim) if d != dim]
norm_of_batch = (x_grad**2).mean(dim=norm_dims, keepdim=True).sqrt()
median_norm = norm_of_batch.median()
cutoff = median_norm * ctx.threshold
inv_mask = (cutoff + norm_of_batch) / (cutoff + eps)
mask = 1.0 / (inv_mask + eps)
x_grad = x_grad * mask
avg_mask = 1.0 / (inv_mask.mean() + eps)
param_grads = [avg_mask * g for g in param_grads]
return (x_grad, None, None) + tuple(param_grads)
class GradientFilter(torch.nn.Module):
"""This is used to filter out elements that have extremely large gradients
in batch and the module parameters with soft masks.
Args:
batch_dim (int):
The batch dimension.
threshold (float):
For each element in batch, its gradient will be
filtered out if the gradient norm is larger than
`grad_norm_threshold * median`, where `median` is the median
value of gradient norms of all elememts in batch.
"""
def __init__(self, batch_dim: int = 1, threshold: float = 10.0):
super(GradientFilter, self).__init__()
self.batch_dim = batch_dim
self.threshold = threshold
def forward(self, x: Tensor, *params: Tensor) -> Tuple[Tensor, ...]:
if torch.jit.is_scripting() or is_jit_tracing():
return (x,) + params
else:
return GradientFilterFunction.apply(
x,
self.batch_dim,
self.threshold,
*params,
)
class BasicNorm(torch.nn.Module):
"""
This is intended to be a simpler, and hopefully cheaper, replacement for
LayerNorm. The observation this is based on, is that Transformer-type
networks, especially with pre-norm, sometimes seem to set one of the
feature dimensions to a large constant value (e.g. 50), which "defeats"
the LayerNorm because the output magnitude is then not strongly dependent
on the other (useful) features. Presumably the weight and bias of the
LayerNorm are required to allow it to do this.
So the idea is to introduce this large constant value as an explicit
parameter, that takes the role of the "eps" in LayerNorm, so the network
doesn't have to do this trick. We make the "eps" learnable.
Args:
num_channels: the number of channels, e.g. 512.
channel_dim: the axis/dimension corresponding to the channel,
interprted as an offset from the input's ndim if negative.
shis is NOT the num_channels; it should typically be one of
{-2, -1, 0, 1, 2, 3}.
eps: the initial "epsilon" that we add as ballast in:
scale = ((input_vec**2).mean() + epsilon)**-0.5
Note: our epsilon is actually large, but we keep the name
to indicate the connection with conventional LayerNorm.
learn_eps: if true, we learn epsilon; if false, we keep it
at the initial value.
"""
def __init__(
self,
num_channels: int,
channel_dim: int = -1, # CAUTION: see documentation.
eps: float = 0.25,
learn_eps: bool = True,
) -> None:
super(BasicNorm, self).__init__()
self.num_channels = num_channels
self.channel_dim = channel_dim
if learn_eps:
self.eps = nn.Parameter(torch.tensor(eps).log().detach())
else:
self.register_buffer("eps", torch.tensor(eps).log().detach())
def forward(self, x: Tensor) -> Tensor:
if not is_jit_tracing():
assert x.shape[self.channel_dim] == self.num_channels
scales = (
torch.mean(x**2, dim=self.channel_dim, keepdim=True) + self.eps.exp()
) ** -0.5
return x * scales
class ScaledLinear(nn.Linear):
"""
A modified version of nn.Linear where the parameters are scaled before
use, via:
weight = self.weight * self.weight_scale.exp()
bias = self.bias * self.bias_scale.exp()
Args:
Accepts the standard args and kwargs that nn.Linear accepts
e.g. in_features, out_features, bias=False.
initial_scale: you can override this if you want to increase
or decrease the initial magnitude of the module's output
(affects the initialization of weight_scale and bias_scale).
Another option, if you want to do something like this, is
to re-initialize the parameters.
initial_speed: this affects how fast the parameter will
learn near the start of training; you can set it to a
value less than one if you suspect that a module
is contributing to instability near the start of training.
Nnote: regardless of the use of this option, it's best to
use schedulers like Noam that have a warm-up period.
Alternatively you can set it to more than 1 if you want it to
initially train faster. Must be greater than 0.
"""
def __init__(
self,
*args,
initial_scale: float = 1.0,
initial_speed: float = 1.0,
**kwargs,
):
super(ScaledLinear, self).__init__(*args, **kwargs)
initial_scale = torch.tensor(initial_scale).log()
self.weight_scale = nn.Parameter(initial_scale.clone().detach())
if self.bias is not None:
self.bias_scale = nn.Parameter(initial_scale.clone().detach())
else:
self.register_parameter("bias_scale", None)
self._reset_parameters(
initial_speed
) # Overrides the reset_parameters in nn.Linear
def _reset_parameters(self, initial_speed: float):
std = 0.1 / initial_speed
a = (3**0.5) * std
nn.init.uniform_(self.weight, -a, a)
if self.bias is not None:
nn.init.constant_(self.bias, 0.0)
fan_in = self.weight.shape[1] * self.weight[0][0].numel()
scale = fan_in**-0.5 # 1/sqrt(fan_in)
with torch.no_grad():
self.weight_scale += torch.tensor(scale / std).log()
def get_weight(self):
return self.weight * self.weight_scale.exp()
def get_bias(self):
if self.bias is None or self.bias_scale is None:
return None
else:
return self.bias * self.bias_scale.exp()
def forward(self, input: Tensor) -> Tensor:
return torch.nn.functional.linear(input, self.get_weight(), self.get_bias())
class ScaledConv1d(nn.Conv1d):
# See docs for ScaledLinear
def __init__(
self,
*args,
initial_scale: float = 1.0,
initial_speed: float = 1.0,
**kwargs,
):
super(ScaledConv1d, self).__init__(*args, **kwargs)
initial_scale = torch.tensor(initial_scale).log()
self.bias_scale: Optional[nn.Parameter] # for torchscript
self.weight_scale = nn.Parameter(initial_scale.clone().detach())
if self.bias is not None:
self.bias_scale = nn.Parameter(initial_scale.clone().detach())
else:
self.register_parameter("bias_scale", None)
self._reset_parameters(
initial_speed
) # Overrides the reset_parameters in base class
def _reset_parameters(self, initial_speed: float):
std = 0.1 / initial_speed
a = (3**0.5) * std
nn.init.uniform_(self.weight, -a, a)
if self.bias is not None:
nn.init.constant_(self.bias, 0.0)
fan_in = self.weight.shape[1] * self.weight[0][0].numel()
scale = fan_in**-0.5 # 1/sqrt(fan_in)
with torch.no_grad():
self.weight_scale += torch.tensor(scale / std).log()
def get_weight(self):
return self.weight * self.weight_scale.exp()
def get_bias(self):
bias = self.bias
bias_scale = self.bias_scale
if bias is None or bias_scale is None:
return None
else:
return bias * bias_scale.exp()
def forward(self, input: Tensor) -> Tensor:
F = torch.nn.functional
if self.padding_mode != "zeros":
return F.conv1d(
F.pad(
input,
self._reversed_padding_repeated_twice,
mode=self.padding_mode,
),
self.get_weight(),
self.get_bias(),
self.stride,
(0,),
self.dilation,
self.groups,
)
return F.conv1d(
input,
self.get_weight(),
self.get_bias(),
self.stride,
self.padding,
self.dilation,
self.groups,
)
class ScaledConv2d(nn.Conv2d):
# See docs for ScaledLinear
def __init__(
self,
*args,
initial_scale: float = 1.0,
initial_speed: float = 1.0,
**kwargs,
):
super(ScaledConv2d, self).__init__(*args, **kwargs)
initial_scale = torch.tensor(initial_scale).log()
self.weight_scale = nn.Parameter(initial_scale.clone().detach())
if self.bias is not None:
self.bias_scale = nn.Parameter(initial_scale.clone().detach())
else:
self.register_parameter("bias_scale", None)
self._reset_parameters(
initial_speed
) # Overrides the reset_parameters in base class
def _reset_parameters(self, initial_speed: float):
std = 0.1 / initial_speed
a = (3**0.5) * std
nn.init.uniform_(self.weight, -a, a)
if self.bias is not None:
nn.init.constant_(self.bias, 0.0)
fan_in = self.weight.shape[1] * self.weight[0][0].numel()
scale = fan_in**-0.5 # 1/sqrt(fan_in)
with torch.no_grad():
self.weight_scale += torch.tensor(scale / std).log()
def get_weight(self):
return self.weight * self.weight_scale.exp()
def get_bias(self):
# see https://github.com/pytorch/pytorch/issues/24135
bias = self.bias
bias_scale = self.bias_scale
if bias is None or bias_scale is None:
return None
else:
return bias * bias_scale.exp()
def _conv_forward(self, input, weight):
F = torch.nn.functional
if self.padding_mode != "zeros":
return F.conv2d(
F.pad(
input,
self._reversed_padding_repeated_twice,
mode=self.padding_mode,
),
weight,
self.get_bias(),
self.stride,
(0, 0),
self.dilation,
self.groups,
)
return F.conv2d(
input,
weight,
self.get_bias(),
self.stride,
self.padding,
self.dilation,
self.groups,
)
def forward(self, input: Tensor) -> Tensor:
return self._conv_forward(input, self.get_weight())
class ScaledLSTM(nn.LSTM):
# See docs for ScaledLinear.
# This class implements LSTM with scaling mechanism, using `torch._VF.lstm`
# Please refer to https://github.com/pytorch/pytorch/blob/master/torch/nn/modules/rnn.py
def __init__(
self,
*args,
initial_scale: float = 1.0,
initial_speed: float = 1.0,
grad_norm_threshold: float = 10.0,
**kwargs,
):
if "bidirectional" in kwargs:
assert kwargs["bidirectional"] is False
super(ScaledLSTM, self).__init__(*args, **kwargs)
initial_scale = torch.tensor(initial_scale).log()
self._scales_names = []
self._scales = []
for name in self._flat_weights_names:
scale_name = name + "_scale"
self._scales_names.append(scale_name)
param = nn.Parameter(initial_scale.clone().detach())
setattr(self, scale_name, param)
self._scales.append(param)
self.grad_filter = GradientFilter(batch_dim=1, threshold=grad_norm_threshold)
self._reset_parameters(
initial_speed
) # Overrides the reset_parameters in base class
def _reset_parameters(self, initial_speed: float):
std = 0.1 / initial_speed
a = (3**0.5) * std
scale = self.hidden_size**-0.5
v = scale / std
for idx, name in enumerate(self._flat_weights_names):
if "weight" in name:
nn.init.uniform_(self._flat_weights[idx], -a, a)
with torch.no_grad():
self._scales[idx] += torch.tensor(v).log()
elif "bias" in name:
nn.init.constant_(self._flat_weights[idx], 0.0)
def _flatten_parameters(self, flat_weights) -> None:
"""Resets parameter data pointer so that they can use faster code paths.
Right now, this works only if the module is on the GPU and cuDNN is enabled.
Otherwise, it's a no-op.
This function is modified from https://github.com/pytorch/pytorch/blob/master/torch/nn/modules/rnn.py # noqa
"""
# Short-circuits if _flat_weights is only partially instantiated
if len(flat_weights) != len(self._flat_weights_names):
return
for w in flat_weights:
if not isinstance(w, Tensor):
return
# Short-circuits if any tensor in flat_weights is not acceptable to cuDNN
# or the tensors in flat_weights are of different dtypes
first_fw = flat_weights[0]
dtype = first_fw.dtype
for fw in flat_weights:
if (
not isinstance(fw.data, Tensor)
or not (fw.data.dtype == dtype)
or not fw.data.is_cuda
or not torch.backends.cudnn.is_acceptable(fw.data)
):
return
# If any parameters alias, we fall back to the slower, copying code path. This is
# a sufficient check, because overlapping parameter buffers that don't completely
# alias would break the assumptions of the uniqueness check in
# Module.named_parameters().
unique_data_ptrs = set(p.data_ptr() for p in flat_weights)
if len(unique_data_ptrs) != len(flat_weights):
return
with torch.cuda.device_of(first_fw):
# Note: no_grad() is necessary since _cudnn_rnn_flatten_weight is
# an inplace operation on self._flat_weights
with torch.no_grad():
if torch._use_cudnn_rnn_flatten_weight():
num_weights = 4 if self.bias else 2
if self.proj_size > 0:
num_weights += 1
torch._cudnn_rnn_flatten_weight(
flat_weights,
num_weights,
self.input_size,
rnn.get_cudnn_mode(self.mode),
self.hidden_size,
self.proj_size,
self.num_layers,
self.batch_first,
bool(self.bidirectional),
)
def _get_flat_weights(self):
"""Get scaled weights, and resets their data pointer."""
flat_weights = []
for idx in range(len(self._flat_weights_names)):
flat_weights.append(self._flat_weights[idx] * self._scales[idx].exp())
self._flatten_parameters(flat_weights)
return flat_weights
def forward(self, input: Tensor, hx: Optional[Tuple[Tensor, Tensor]] = None):
# This function is modified from https://github.com/pytorch/pytorch/blob/master/torch/nn/modules/rnn.py # noqa
# The change for calling `_VF.lstm()` is:
# self._flat_weights -> self._get_flat_weights()
if hx is None:
h_zeros = torch.zeros(
self.num_layers,
input.size(1),
self.proj_size if self.proj_size > 0 else self.hidden_size,
dtype=input.dtype,
device=input.device,
)
c_zeros = torch.zeros(
self.num_layers,
input.size(1),
self.hidden_size,
dtype=input.dtype,
device=input.device,
)
hx = (h_zeros, c_zeros)
self.check_forward_args(input, hx, None)
flat_weights = self._get_flat_weights()
input, *flat_weights = self.grad_filter(input, *flat_weights)
result = _VF.lstm(
input,
hx,
flat_weights,
self.bias,
self.num_layers,
self.dropout,
self.training,
self.bidirectional,
self.batch_first,
)
output = result[0]
hidden = result[1:]
return output, hidden
class ActivationBalancer(torch.nn.Module):
"""
Modifies the backpropped derivatives of a function to try to encourage, for
each channel, that it is positive at least a proportion `threshold` of the
time. It does this by multiplying negative derivative values by up to
(1+max_factor), and positive derivative values by up to (1-max_factor),
interpolated from 1 at the threshold to those extremal values when none
of the inputs are positive.
Args:
channel_dim: the dimension/axis corresponding to the channel, e.g.
-1, 0, 1, 2; will be interpreted as an offset from x.ndim if negative.
min_positive: the minimum, per channel, of the proportion of the time
that (x > 0), below which we start to modify the derivatives.
max_positive: the maximum, per channel, of the proportion of the time
that (x > 0), above which we start to modify the derivatives.
max_factor: the maximum factor by which we modify the derivatives for
either the sign constraint or the magnitude constraint;
e.g. with max_factor=0.02, the the derivatives would be multiplied by
values in the range [0.98..1.02].
min_abs: the minimum average-absolute-value per channel, which
we allow, before we start to modify the derivatives to prevent
this.
max_abs: the maximum average-absolute-value per channel, which
we allow, before we start to modify the derivatives to prevent
this.
balance_prob: the probability to apply the ActivationBalancer.
"""
def __init__(
self,
channel_dim: int,
min_positive: float = 0.05,
max_positive: float = 0.95,
max_factor: float = 0.01,
min_abs: float = 0.2,
max_abs: float = 100.0,
balance_prob: float = 0.25,
):
super(ActivationBalancer, self).__init__()
self.channel_dim = channel_dim
self.min_positive = min_positive
self.max_positive = max_positive
self.max_factor = max_factor
self.min_abs = min_abs
self.max_abs = max_abs
assert 0 < balance_prob <= 1, balance_prob
self.balance_prob = balance_prob
def forward(self, x: Tensor) -> Tensor:
if random.random() >= self.balance_prob:
return x
return ActivationBalancerFunction.apply(
x,
self.channel_dim,
self.min_positive,
self.max_positive,
self.max_factor / self.balance_prob,
self.min_abs,
self.max_abs,
)
class DoubleSwishFunction(torch.autograd.Function):
"""
double_swish(x) = x * torch.sigmoid(x-1)
This is a definition, originally motivated by its close numerical
similarity to swish(swish(x)), where swish(x) = x * sigmoid(x).
Memory-efficient derivative computation:
double_swish(x) = x * s, where s(x) = torch.sigmoid(x-1)
double_swish'(x) = d/dx double_swish(x) = x * s'(x) + x' * s(x) = x * s'(x) + s(x).
Now, s'(x) = s(x) * (1-s(x)).
double_swish'(x) = x * s'(x) + s(x).
= x * s(x) * (1-s(x)) + s(x).
= double_swish(x) * (1-s(x)) + s(x)
... so we just need to remember s(x) but not x itself.
"""
@staticmethod
def forward(ctx, x: Tensor) -> Tensor:
x = x.detach()
s = torch.sigmoid(x - 1.0)
y = x * s
ctx.save_for_backward(s, y)
return y
@staticmethod
def backward(ctx, y_grad: Tensor) -> Tensor:
s, y = ctx.saved_tensors
return (y * (1 - s) + s) * y_grad
class DoubleSwish(torch.nn.Module):
def forward(self, x: Tensor) -> Tensor:
"""Return double-swish activation function which is an approximation to Swish(Swish(x)),
that we approximate closely with x * sigmoid(x-1).
"""
if torch.jit.is_scripting() or is_jit_tracing():
return x * torch.sigmoid(x - 1.0)
else:
return DoubleSwishFunction.apply(x)
class ScaledEmbedding(nn.Module):
r"""This is a modified version of nn.Embedding that introduces a learnable scale
on the parameters. Note: due to how we initialize it, it's best used with
schedulers like Noam that have a warmup period.
It is a simple lookup table that stores embeddings of a fixed dictionary and size.
This module is often used to store word embeddings and retrieve them using indices.
The input to the module is a list of indices, and the output is the corresponding
word embeddings.
Args:
num_embeddings (int): size of the dictionary of embeddings
embedding_dim (int): the size of each embedding vector
padding_idx (int, optional): If given, pads the output with the embedding vector at :attr:`padding_idx`
(initialized to zeros) whenever it encounters the index.
scale_grad_by_freq (boolean, optional): If given, this will scale gradients by the inverse of frequency of
the words in the mini-batch. Default ``False``.
sparse (bool, optional): If ``True``, gradient w.r.t. :attr:`weight` matrix will be a sparse tensor.
See Notes for more details regarding sparse gradients.
initial_speed (float, optional): This affects how fast the parameter will
learn near the start of training; you can set it to a value less than
one if you suspect that a module is contributing to instability near
the start of training. Note: regardless of the use of this option,
it's best to use schedulers like Noam that have a warm-up period.
Alternatively you can set it to more than 1 if you want it to
initially train faster. Must be greater than 0.
Attributes:
weight (Tensor): the learnable weights of the module of shape (num_embeddings, embedding_dim)
initialized from :math:`\mathcal{N}(0, 1)`
Shape:
- Input: :math:`(*)`, LongTensor of arbitrary shape containing the indices to extract
- Output: :math:`(*, H)`, where `*` is the input shape and :math:`H=\text{embedding\_dim}`
.. note::
Keep in mind that only a limited number of optimizers support
sparse gradients: currently it's :class:`optim.SGD` (`CUDA` and `CPU`),
:class:`optim.SparseAdam` (`CUDA` and `CPU`) and :class:`optim.Adagrad` (`CPU`)
.. note::
With :attr:`padding_idx` set, the embedding vector at
:attr:`padding_idx` is initialized to all zeros. However, note that this
vector can be modified afterwards, e.g., using a customized
initialization method, and thus changing the vector used to pad the
output. The gradient for this vector from :class:`~torch.nn.Embedding`
is always zero.
Examples::
>>> # an Embedding module containing 10 tensors of size 3
>>> embedding = nn.Embedding(10, 3)
>>> # a batch of 2 samples of 4 indices each
>>> input = torch.LongTensor([[1,2,4,5],[4,3,2,9]])
>>> embedding(input)
tensor([[[-0.0251, -1.6902, 0.7172],
[-0.6431, 0.0748, 0.6969],
[ 1.4970, 1.3448, -0.9685],
[-0.3677, -2.7265, -0.1685]],
[[ 1.4970, 1.3448, -0.9685],
[ 0.4362, -0.4004, 0.9400],
[-0.6431, 0.0748, 0.6969],
[ 0.9124, -2.3616, 1.1151]]])
>>> # example with padding_idx
>>> embedding = nn.Embedding(10, 3, padding_idx=0)
>>> input = torch.LongTensor([[0,2,0,5]])
>>> embedding(input)
tensor([[[ 0.0000, 0.0000, 0.0000],
[ 0.1535, -2.0309, 0.9315],
[ 0.0000, 0.0000, 0.0000],
[-0.1655, 0.9897, 0.0635]]])
"""
__constants__ = [
"num_embeddings",
"embedding_dim",
"padding_idx",
"scale_grad_by_freq",
"sparse",
]
num_embeddings: int
embedding_dim: int
padding_idx: int
scale_grad_by_freq: bool
weight: Tensor
sparse: bool
def __init__(
self,
num_embeddings: int,
embedding_dim: int,
padding_idx: Optional[int] = None,
scale_grad_by_freq: bool = False,
sparse: bool = False,
initial_speed: float = 1.0,
) -> None:
super(ScaledEmbedding, self).__init__()
self.num_embeddings = num_embeddings
self.embedding_dim = embedding_dim
if padding_idx is not None:
if padding_idx > 0:
assert (
padding_idx < self.num_embeddings
), "Padding_idx must be within num_embeddings"
elif padding_idx < 0:
assert (
padding_idx >= -self.num_embeddings
), "Padding_idx must be within num_embeddings"
padding_idx = self.num_embeddings + padding_idx
self.padding_idx = padding_idx
self.scale_grad_by_freq = scale_grad_by_freq
self.scale = nn.Parameter(torch.zeros(())) # see reset_parameters()
self.sparse = sparse
self.weight = nn.Parameter(torch.Tensor(num_embeddings, embedding_dim))
self.reset_parameters(initial_speed)
def reset_parameters(self, initial_speed: float = 1.0) -> None:
std = 0.1 / initial_speed
nn.init.normal_(self.weight, std=std)
nn.init.constant_(self.scale, torch.tensor(1.0 / std).log())
if self.padding_idx is not None:
with torch.no_grad():
self.weight[self.padding_idx].fill_(0)
def forward(self, input: Tensor) -> Tensor:
F = torch.nn.functional
scale = self.scale.exp()
if input.numel() < self.num_embeddings:
return (
F.embedding(
input,
self.weight,
self.padding_idx,
None,
2.0, # None, 2.0 relate to normalization
self.scale_grad_by_freq,
self.sparse,
)
* scale
)
else:
return F.embedding(
input,
self.weight * scale,
self.padding_idx,
None,
2.0, # None, 2.0 relates to normalization
self.scale_grad_by_freq,
self.sparse,
)
def extra_repr(self) -> str:
# s = "{num_embeddings}, {embedding_dim}, scale={scale}"
s = "{num_embeddings}, {embedding_dim}"
if self.padding_idx is not None:
s += ", padding_idx={padding_idx}"
if self.scale_grad_by_freq is not False:
s += ", scale_grad_by_freq={scale_grad_by_freq}"
if self.sparse is not False:
s += ", sparse=True"
return s.format(**self.__dict__)
def _test_activation_balancer_sign():
probs = torch.arange(0, 1, 0.01)
N = 1000
x = 1.0 * (torch.rand(probs.numel(), N) < probs.unsqueeze(-1))
x = x.detach()
x.requires_grad = True
m = ActivationBalancer(
channel_dim=0,
min_positive=0.05,
max_positive=0.95,
max_factor=0.2,
min_abs=0.0,
)
y_grad = torch.sign(torch.randn(probs.numel(), N))
y = m(x)
y.backward(gradient=y_grad)
print("_test_activation_balancer_sign: x = ", x)
print("_test_activation_balancer_sign: y grad = ", y_grad)
print("_test_activation_balancer_sign: x grad = ", x.grad)
def _test_activation_balancer_magnitude():
magnitudes = torch.arange(0, 1, 0.01)
N = 1000
x = torch.sign(torch.randn(magnitudes.numel(), N)) * magnitudes.unsqueeze(-1)
x = x.detach()
x.requires_grad = True
m = ActivationBalancer(
channel_dim=0,
min_positive=0.0,
max_positive=1.0,
max_factor=0.2,
min_abs=0.2,
max_abs=0.8,
)
y_grad = torch.sign(torch.randn(magnitudes.numel(), N))
y = m(x)
y.backward(gradient=y_grad)
print("_test_activation_balancer_magnitude: x = ", x)
print("_test_activation_balancer_magnitude: y grad = ", y_grad)
print("_test_activation_balancer_magnitude: x grad = ", x.grad)
def _test_basic_norm():
num_channels = 128
m = BasicNorm(num_channels=num_channels, channel_dim=1)
x = torch.randn(500, num_channels)
y = m(x)
assert y.shape == x.shape
x_rms = (x**2).mean().sqrt()
y_rms = (y**2).mean().sqrt()
print("x rms = ", x_rms)
print("y rms = ", y_rms)
assert y_rms < x_rms
assert y_rms > 0.5 * x_rms
def _test_double_swish_deriv():
x = torch.randn(10, 12, dtype=torch.double) * 0.5
x.requires_grad = True
m = DoubleSwish()
torch.autograd.gradcheck(m, x)
def _test_scaled_lstm():
N, L = 2, 30
dim_in, dim_hidden = 10, 20
m = ScaledLSTM(input_size=dim_in, hidden_size=dim_hidden, bias=True)
x = torch.randn(L, N, dim_in)
h0 = torch.randn(1, N, dim_hidden)
c0 = torch.randn(1, N, dim_hidden)
y, (h, c) = m(x, (h0, c0))
assert y.shape == (L, N, dim_hidden)
assert h.shape == (1, N, dim_hidden)
assert c.shape == (1, N, dim_hidden)
def _test_grad_filter():
threshold = 50.0
time, batch, channel = 200, 5, 128
grad_filter = GradientFilter(batch_dim=1, threshold=threshold)
for i in range(2):
x = torch.randn(time, batch, channel, requires_grad=True)
w = nn.Parameter(torch.ones(5))
b = nn.Parameter(torch.zeros(5))
x_out, w_out, b_out = grad_filter(x, w, b)
w_out_grad = torch.randn_like(w)
b_out_grad = torch.randn_like(b)
x_out_grad = torch.rand_like(x)
if i % 2 == 1:
# The gradient norm of the first element must be larger than
# `threshold * median`, where `median` is the median value
# of gradient norms of all elements in batch.
x_out_grad[:, 0, :] = torch.full((time, channel), threshold)
torch.autograd.backward(
[x_out, w_out, b_out], [x_out_grad, w_out_grad, b_out_grad]
)
print(
"_test_grad_filter: for gradient norms, the first element > median * threshold ", # noqa
i % 2 == 1,
)
print(
"_test_grad_filter: x_out_grad norm = ",
(x_out_grad**2).mean(dim=(0, 2)).sqrt(),
)
print(
"_test_grad_filter: x.grad norm = ",
(x.grad**2).mean(dim=(0, 2)).sqrt(),
)
print("_test_grad_filter: w_out_grad = ", w_out_grad)
print("_test_grad_filter: w.grad = ", w.grad)
print("_test_grad_filter: b_out_grad = ", b_out_grad)
print("_test_grad_filter: b.grad = ", b.grad)
if __name__ == "__main__":
_test_activation_balancer_sign()
_test_activation_balancer_magnitude()
_test_basic_norm()
_test_double_swish_deriv()
_test_scaled_lstm()
_test_grad_filter()