161 lines
5.7 KiB
Python
161 lines
5.7 KiB
Python
# Copyright (c) Facebook, Inc. and its affiliates.
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#
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# This source code is licensed under the MIT license found in the
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# LICENSE file in the root directory of this source tree.
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import math
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import torch
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import torch.nn as nn
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import torch.nn.functional as F
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class AdaptiveMask(nn.Module):
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"""Soft masking function for adaptive size.
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It masks out the last K values of an input. The masking value
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goes from 1 to 0 gradually, so K can be learned with
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back-propagation.
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Args:
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max_size: maximum size (i.e. input dimension)
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ramp_size: size of the ramp going from 0 to 1
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init_val: initial size proportion not to be masked out
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shape: learn multiple sizes independent of each other
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"""
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def __init__(self, max_size, ramp_size, init_val=0, shape=(1,)):
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nn.Module.__init__(self)
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self._max_size = max_size
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self._ramp_size = ramp_size
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self.current_val = nn.Parameter(torch.zeros(*shape) + init_val)
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mask_template = torch.linspace(1 - max_size, 0, steps=max_size)
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self.register_buffer("mask_template", mask_template)
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def forward(self, x):
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mask = self.mask_template.float() + self.current_val.float() * self._max_size
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mask = mask / self._ramp_size + 1
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mask = mask.clamp(0, 1)
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if x.size(-1) < self._max_size:
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# the input could have been trimmed beforehand to save computation
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mask = mask.narrow(-1, self._max_size - x.size(-1), x.size(-1))
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x = (x * mask).type_as(x)
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return x
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def get_current_max_size(self, include_ramp=True):
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current_size = math.ceil(self.current_val.max().item() * self._max_size)
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if include_ramp:
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current_size += self._ramp_size
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current_size = max(0, min(self._max_size, current_size))
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return current_size
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def get_current_avg_size(self, include_ramp=True):
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current_size = math.ceil(
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self.current_val.float().mean().item() * self._max_size
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)
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if include_ramp:
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current_size += self._ramp_size
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current_size = max(0, min(self._max_size, current_size))
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return current_size
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def clamp_param(self):
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"""this need to be called after each update"""
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self.current_val.data.clamp_(0, 1)
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class AdaptiveSpan(nn.Module):
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"""Adaptive attention span for Transformerself.
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This module learns an attention span length from data for each
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self-attention head.
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Args:
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attn_span: maximum attention span
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adapt_span_loss: loss coefficient for the span length
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adapt_span_ramp: length of the masking ramp
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adapt_span_init: initial size ratio
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adapt_span_cache: adapt cache size to reduce memory usage
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"""
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def __init__(
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self,
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attn_span,
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adapt_span_ramp,
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adapt_span_init,
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n_head,
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adapt_span_layer,
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**kargs
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):
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nn.Module.__init__(self)
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self._max_span = attn_span
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self._n_head = n_head
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self._adapt_span_layer = adapt_span_layer
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if self._adapt_span_layer:
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self._mask = AdaptiveMask(
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max_size=self._max_span,
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ramp_size=adapt_span_ramp,
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init_val=adapt_span_init,
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)
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else:
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self._mask = AdaptiveMask(
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max_size=self._max_span,
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ramp_size=adapt_span_ramp,
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init_val=adapt_span_init,
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shape=(n_head, 1, 1),
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)
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def forward(self, attn, normalize=True):
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"""mask attention with the right span"""
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# batch and head dimensions are merged together, so separate them first
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self.clamp_param()
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if self._adapt_span_layer:
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attn = self._mask(attn)
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else:
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B = attn.size(0) # batch size
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M = attn.size(1) # block size
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attn = attn.reshape(B // self._n_head, self._n_head, M, -1)
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attn = self._mask(attn)
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attn = attn.view(B, M, -1)
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return attn
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def get_trim_len(self):
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"""how much of memory can be trimmed to reduce computation"""
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L = self._max_span
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trim_len = min(L - 1, L - self._mask.get_current_max_size())
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# too fine granularity might be bad for the memory management
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trim_len = math.floor(trim_len / 64) * 64
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return trim_len
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def trim_memory(self, query, key, value, key_pe):
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"""trim out unnecessary memory beforehand to reduce computation"""
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trim_len = self.get_trim_len()
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cache_size = key.size(1) - query.size(1)
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trim_len_cache = trim_len - (self._max_span - cache_size)
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if trim_len_cache > 0:
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key = key[:, trim_len_cache:, :]
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value = value[:, trim_len_cache:, :]
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elif trim_len_cache < 0:
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# cache is too short! this happens when validation resumes
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# after a lot of updates.
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key = F.pad(key, [0, 0, -trim_len_cache, 0])
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value = F.pad(value, [0, 0, -trim_len_cache, 0])
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if trim_len > 0:
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if key_pe is not None:
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key_pe = key_pe[:, :, trim_len:]
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return key, value, key_pe
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def get_cache_size(self):
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"""determine how long the cache should be"""
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trim_len = self.get_trim_len()
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# give a buffer of 64 steps since a span might increase
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# in future updates
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return min(self._max_span, self._max_span - trim_len + 64)
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def get_loss(self):
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"""a loss term for regularizing the span length"""
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return self._max_span * self._mask.current_val.float().mean()
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def get_current_max_span(self):
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return self._mask.get_current_max_size()
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def get_current_avg_span(self):
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return self._mask.get_current_avg_size()
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def clamp_param(self):
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self._mask.clamp_param()
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