torch/nn/utils/rnn.py - platform/external/pytorch - Git at Google

 from collections import namedtuple
 import warnings

 import torch
 from ... import _VF
 from ..._jit_internal import Optional


 PackedSequence_ = namedtuple('PackedSequence',
                              ['data', 'batch_sizes', 'sorted_indices', 'unsorted_indices'])

 # type annotation for PackedSequence_ to make it compatible with TorchScript
 PackedSequence_.__annotations__ = {'data': torch.Tensor, 'batch_sizes': torch.Tensor,
                                    'sorted_indices': Optional[torch.Tensor],
                                    'unsorted_indices': Optional[torch.Tensor]}

 def bind(optional, fn):
     if optional is None:
         return None
     return fn(optional)


 class PackedSequence(PackedSequence_):
     r"""Holds the data and list of :attr:`batch_sizes` of a packed sequence.

     All RNN modules accept packed sequences as inputs.

     Note:
         Instances of this class should never be created manually. They are meant
         to be instantiated by functions like :func:`pack_padded_sequence`.

         Batch sizes represent the number elements at each sequence step in
         the batch, not the varying sequence lengths passed to
         :func:`pack_padded_sequence`.  For instance, given data ``abc`` and ``x``
         the :class:`PackedSequence` would contain data ``axbc`` with
         ``batch_sizes=[2,1,1]``.

     Attributes:
         data (Tensor): Tensor containing packed sequence
         batch_sizes (Tensor): Tensor of integers holding
             information about the batch size at each sequence step
         sorted_indices (Tensor, optional): Tensor of integers holding how this
             :class:`PackedSequence` is constructed from sequences.
         unsorted_indices (Tensor, optional): Tensor of integers holding how this
             to recover the original sequences with correct order.

     .. note::
         :attr:`data` can be on arbitrary device and of arbitrary dtype.
         :attr:`sorted_indices` and :attr:`unsorted_indices` must be ``torch.int64``
         tensors on the same device as :attr:`data`.

         However, :attr:`batch_sizes` should always be a CPU ``torch.int64`` tensor.

         This invariant is maintained throughout :class:`PackedSequence` class,
         and all functions that construct a `:class:PackedSequence` in PyTorch
         (i.e., they only pass in tensors conforming to this constraint).

     """
     def __new__(cls, data, batch_sizes=None, sorted_indices=None, unsorted_indices=None):
         return super(PackedSequence, cls).__new__(
             cls,
             *_packed_sequence_init_args(data, batch_sizes, sorted_indices,
                                         unsorted_indices))

     # NOTE [ device and dtype of a PackedSequence ]
     #
     # See the note above in doc string (starting with ":attr:`data` can be on
     # arbitrary device...").
     def pin_memory(self):
         # Why not convert `batch_sizes`?
         # See NOTE [ device and dtype of a PackedSequence ]
         return type(self)(self.data.pin_memory(), self.batch_sizes,
                           bind(self.sorted_indices, lambda t: t.pin_memory()),
                           bind(self.unsorted_indices, lambda t: t.pin_memory()))

     def cuda(self, *args, **kwargs):
         # Tests to see if 'cuda' should be added to kwargs
         ex = torch.tensor((), dtype=self.data.dtype, device=self.data.device).to(*args, **kwargs)
         if ex.is_cuda:
             return self.to(*args, **kwargs)
         return self.to(*args, device='cuda', **kwargs)

     def cpu(self, *args, **kwargs):

         ex = torch.tensor((), dtype=self.data.dtype, device=self.data.device).to(*args, **kwargs)
         if ex.device.type == 'cpu':
             return self.to(*args, **kwargs)
         return self.to(*args, device='cpu', **kwargs)

     def double(self):
         return self.to(dtype=torch.double)

     def float(self):
         return self.to(dtype=torch.float)

     def half(self):
         return self.to(dtype=torch.half)

     def long(self):
         return self.to(dtype=torch.long)

     def int(self):
         return self.to(dtype=torch.int)

     def short(self):
         return self.to(dtype=torch.short)

     def char(self):
         return self.to(dtype=torch.int8)

     def byte(self):
         return self.to(dtype=torch.uint8)

     def to(self, *args, **kwargs):
         r"""Performs dtype and/or device conversion on `self.data`.

         It has similar signature as :meth:`torch.Tensor.to`, except optional
         arguments like `non_blocking` and `copy` should be passed as kwargs,
         not args, or they will not apply to the index tensors.

         .. note::

             If the ``self.data`` Tensor already has the correct :class:`torch.dtype`
             and :class:`torch.device`, then ``self`` is returned.
             Otherwise, returns a copy with the desired configuration.
         """

         # Why not convert `batch_sizes`?
         # See NOTE [ device and dtype of a PackedSequence ]
         data = self.data.to(*args, **kwargs)
         if data is self.data:
             return self
         else:
             # Does not forward device or dtype arg/kwargs, device is set from data.device
             kwargs = {k : v for k, v in filter(lambda t: t[0] != 'device' and t[0] != 'dtype', kwargs.items())}
             sorted_indices = bind(self.sorted_indices, lambda t: t.to(data.device, **kwargs))
             unsorted_indices = bind(self.unsorted_indices, lambda t: t.to(data.device, **kwargs))
             return type(self)(data, self.batch_sizes, sorted_indices, unsorted_indices)

     @property
     def is_cuda(self):
         r"""Returns true if `self.data` stored on a gpu"""
         return self.data.is_cuda

     def is_pinned(self):
         r"""Returns true if `self.data` stored on in pinned memory"""
         return self.data.is_pinned()


 # TorchScript doesn't support constructors on named tuples, so we use this helper
 # method to construct PackedSequence
 def _packed_sequence_init_args(data, batch_sizes=None, sorted_indices=None, unsorted_indices=None):
     # type: (Tensor, Optional[Tensor], Optional[Tensor], Optional[Tensor]) -> Tuple[Tensor, Tensor, Optional[Tensor], Optional[Tensor]]  # noqa
     # NB: if unsorted_indices is provided, it should be the inverse permutation
     # to sorted_indices. Don't assert it here because the PackedSequence ctor
     # should only be used internally.

     if unsorted_indices is None:
         unsorted_indices = invert_permutation(sorted_indices)

     # support being called as `PackedSequence(data, batch_sizes, sorted_indices)`
     if batch_sizes is not None:
         # TODO: Re-enable this check (.type isn't supported in TorchScript)
         if batch_sizes.device.type != 'cpu':
             raise ValueError(
                 "batch_sizes should always be on CPU. "
                 "Instances of PackedSequence should never be created manually. "
                 "They should be instantiated by functions like pack_sequence "
                 "and pack_padded_sequences in nn.utils.rnn. "
                 "https://pytorch.org/docs/stable/nn.html#torch.nn.utils.rnn.pack_sequence")
         return data, batch_sizes, sorted_indices, unsorted_indices

     # support being called as `PackedSequence((data, batch_sizes), *, sorted_indices)`
     else:
         assert isinstance(data, (list, tuple)) and len(data) == 2
         return data[0], data[1], sorted_indices, unsorted_indices


 def _packed_sequence_init(data, batch_sizes=None, sorted_indices=None, unsorted_indices=None):
     # type: (Tensor, Optional[Tensor], Optional[Tensor], Optional[Tensor]) -> PackedSequence
     data, batch_sizes, sorted_indices, unsorted_indices = _packed_sequence_init_args(
         data, batch_sizes, sorted_indices, unsorted_indices)
     return PackedSequence(data, batch_sizes, sorted_indices, unsorted_indices)


 def invert_permutation(permutation):
     # type: (Optional[Tensor]) -> Optional[Tensor]
     if permutation is None:
         return None
     output = torch.empty_like(permutation, memory_format=torch.legacy_contiguous_format)
     output.scatter_(0, permutation,
                     torch.arange(0, permutation.numel(), device=permutation.device))
     return output


 def pack_padded_sequence(input, lengths, batch_first=False, enforce_sorted=True):
     # type: (Tensor, Tensor, bool, bool) -> PackedSequence
     r"""Packs a Tensor containing padded sequences of variable length.

     :attr:`input` can be of size ``T x B x *`` where `T` is the length of the
     longest sequence (equal to ``lengths[0]``), ``B`` is the batch size, and
     ``*`` is any number of dimensions (including 0). If ``batch_first`` is
     ``True``, ``B x T x *`` :attr:`input` is expected.

     For unsorted sequences, use `enforce_sorted = False`. If :attr:`enforce_sorted` is
     ``True``, the sequences should be sorted by length in a decreasing order, i.e.
     ``input[:,0]`` should be the longest sequence, and ``input[:,B-1]`` the shortest
     one. `enforce_sorted = True` is only necessary for ONNX export.

     Note:
         This function accepts any input that has at least two dimensions. You
         can apply it to pack the labels, and use the output of the RNN with
         them to compute the loss directly. A Tensor can be retrieved from
         a :class:`PackedSequence` object by accessing its ``.data`` attribute.

     Arguments:
         input (Tensor): padded batch of variable length sequences.
         lengths (Tensor): list of sequences lengths of each batch element.
         batch_first (bool, optional): if ``True``, the input is expected in ``B x T x *``
             format.
         enforce_sorted (bool, optional): if ``True``, the input is expected to
             contain sequences sorted by length in a decreasing order. If
             ``False``, the input will get sorted unconditionally. Default: ``True``.

     Returns:
         a :class:`PackedSequence` object
     """
     if torch._C._get_tracing_state() and not isinstance(lengths, torch.Tensor):
         warnings.warn('pack_padded_sequence has been called with a Python list of '
                       'sequence lengths. The tracer cannot track the data flow of Python '
                       'values, and it will treat them as constants, likely rendering '
                       'the trace incorrect for any other combination of lengths.',
                       stacklevel=2)
     lengths = torch.as_tensor(lengths, dtype=torch.int64)
     if enforce_sorted:
         sorted_indices = None
     else:
         lengths, sorted_indices = torch.sort(lengths, descending=True)
         sorted_indices = sorted_indices.to(input.device)
         batch_dim = 0 if batch_first else 1
         input = input.index_select(batch_dim, sorted_indices)

     data, batch_sizes = \
         _VF._pack_padded_sequence(input, lengths, batch_first)
     return _packed_sequence_init(data, batch_sizes, sorted_indices, None)


 def pad_packed_sequence(sequence, batch_first=False, padding_value=0.0, total_length=None):
     # type: (PackedSequence, bool, float, Optional[int]) -> Tuple[Tensor, Tensor]
     r"""Pads a packed batch of variable length sequences.

     It is an inverse operation to :func:`pack_padded_sequence`.

     The returned Tensor's data will be of size ``T x B x *``, where `T` is the length
     of the longest sequence and `B` is the batch size. If ``batch_first`` is True,
     the data will be transposed into ``B x T x *`` format.

     Example:
         >>> from torch.nn.utils.rnn import pack_padded_sequence, pad_packed_sequence
         >>> seq = torch.tensor([[1,2,0], [3,0,0], [4,5,6]])
         >>> lens = [2, 1, 3]
         >>> packed = pack_padded_sequence(seq, lens, batch_first=True, enforce_sorted=False)
         >>> packed
         PackedSequence(data=tensor([4, 1, 3, 5, 2, 6]), batch_sizes=tensor([3, 2, 1]),
                        sorted_indices=tensor([2, 0, 1]), unsorted_indices=tensor([1, 2, 0]))
         >>> seq_unpacked, lens_unpacked = pad_packed_sequence(packed, batch_first=True)
         >>> seq_unpacked
         tensor([[1, 2, 0],
                 [3, 0, 0],
                 [4, 5, 6]])
         >>> lens_unpacked
         tensor([2, 1, 3])

     .. note::
         :attr:`total_length` is useful to implement the
         ``pack sequence -> recurrent network -> unpack sequence`` pattern in a
         :class:`~torch.nn.Module` wrapped in :class:`~torch.nn.DataParallel`.
         See :ref:`this FAQ section <pack-rnn-unpack-with-data-parallelism>` for
         details.

     Arguments:
         sequence (PackedSequence): batch to pad
         batch_first (bool, optional): if ``True``, the output will be in ``B x T x *``
             format.
         padding_value (float, optional): values for padded elements.
         total_length (int, optional): if not ``None``, the output will be padded to
             have length :attr:`total_length`. This method will throw :class:`ValueError`
             if :attr:`total_length` is less than the max sequence length in
             :attr:`sequence`.

     Returns:
         Tuple of Tensor containing the padded sequence, and a Tensor
         containing the list of lengths of each sequence in the batch.
         Batch elements will be re-ordered as they were ordered originally when
         the batch was passed to ``pack_padded_sequence`` or ``pack_sequence``.


     """
     max_seq_length = sequence.batch_sizes.size(0)
     if total_length is not None:
         if total_length < max_seq_length:
             raise ValueError("Expected total_length to be at least the length "
                              "of the longest sequence in input, but got "
                              "total_length={} and max sequence length being {}"
                              .format(total_length, max_seq_length))
         max_seq_length = total_length
     padded_output, lengths = _VF._pad_packed_sequence(
         sequence.data, sequence.batch_sizes, batch_first, padding_value, max_seq_length)
     unsorted_indices = sequence.unsorted_indices
     if unsorted_indices is not None:
         batch_dim = 0 if batch_first else 1
         return padded_output.index_select(batch_dim, unsorted_indices), lengths[unsorted_indices]
     return padded_output, lengths


 def pad_sequence(sequences, batch_first=False, padding_value=0):
     r"""Pad a list of variable length Tensors with ``padding_value``

     ``pad_sequence`` stacks a list of Tensors along a new dimension,
     and pads them to equal length. For example, if the input is list of
     sequences with size ``L x *`` and if batch_first is False, and ``T x B x *``
     otherwise.

     `B` is batch size. It is equal to the number of elements in ``sequences``.
     `T` is length of the longest sequence.
     `L` is length of the sequence.
     `*` is any number of trailing dimensions, including none.

     Example:
         >>> from torch.nn.utils.rnn import pad_sequence
         >>> a = torch.ones(25, 300)
         >>> b = torch.ones(22, 300)
         >>> c = torch.ones(15, 300)
         >>> pad_sequence([a, b, c]).size()
         torch.Size([25, 3, 300])

     Note:
         This function returns a Tensor of size ``T x B x *`` or ``B x T x *``
         where `T` is the length of the longest sequence. This function assumes
         trailing dimensions and type of all the Tensors in sequences are same.

     Arguments:
         sequences (list[Tensor]): list of variable length sequences.
         batch_first (bool, optional): output will be in ``B x T x *`` if True, or in
             ``T x B x *`` otherwise
         padding_value (float, optional): value for padded elements. Default: 0.

     Returns:
         Tensor of size ``T x B x *`` if :attr:`batch_first` is ``False``.
         Tensor of size ``B x T x *`` otherwise
     """

     # assuming trailing dimensions and type of all the Tensors
     # in sequences are same and fetching those from sequences[0]
     max_size = sequences[0].size()
     trailing_dims = max_size[1:]
     max_len = max([s.size(0) for s in sequences])
     if batch_first:
         out_dims = (len(sequences), max_len) + trailing_dims
     else:
         out_dims = (max_len, len(sequences)) + trailing_dims

     out_tensor = sequences[0].data.new(*out_dims).fill_(padding_value)
     for i, tensor in enumerate(sequences):
         length = tensor.size(0)
         # use index notation to prevent duplicate references to the tensor
         if batch_first:
             out_tensor[i, :length, ...] = tensor
         else:
             out_tensor[:length, i, ...] = tensor

     return out_tensor


 def pack_sequence(sequences, enforce_sorted=True):
     # type: (List[Tensor], bool) -> PackedSequence
     r"""Packs a list of variable length Tensors

     ``sequences`` should be a list of Tensors of size ``L x *``, where `L` is
     the length of a sequence and `*` is any number of trailing dimensions,
     including zero.

     For unsorted sequences, use `enforce_sorted = False`. If ``enforce_sorted``
     is ``True``, the sequences should be sorted in the order of decreasing length.
     ``enforce_sorted = True`` is only necessary for ONNX export.


     Example:
         >>> from torch.nn.utils.rnn import pack_sequence
         >>> a = torch.tensor([1,2,3])
         >>> b = torch.tensor([4,5])
         >>> c = torch.tensor([6])
         >>> pack_sequence([a, b, c])
         PackedSequence(data=tensor([ 1,  4,  6,  2,  5,  3]), batch_sizes=tensor([ 3,  2,  1]))


     Arguments:
         sequences (list[Tensor]): A list of sequences of decreasing length.
         enforce_sorted (bool, optional): if ``True``, checks that the input
             contains sequences sorted by length in a decreasing order. If
             ``False``, this condition is not checked. Default: ``True``.

     Returns:
         a :class:`PackedSequence` object
     """
     lengths = [v.size(0) for v in sequences]
     return pack_padded_sequence(pad_sequence(sequences), lengths, enforce_sorted=enforce_sorted)
	from collections import namedtuple
	import warnings

	import torch
	from ... import _VF
	from ..._jit_internal import Optional


	PackedSequence_ = namedtuple('PackedSequence',
	['data', 'batch_sizes', 'sorted_indices', 'unsorted_indices'])

	# type annotation for PackedSequence_ to make it compatible with TorchScript
	PackedSequence_.__annotations__ = {'data': torch.Tensor, 'batch_sizes': torch.Tensor,
	'sorted_indices': Optional[torch.Tensor],
	'unsorted_indices': Optional[torch.Tensor]}

	def bind(optional, fn):
	if optional is None:
	return None
	return fn(optional)


	class PackedSequence(PackedSequence_):
	r"""Holds the data and list of :attr:`batch_sizes` of a packed sequence.

	All RNN modules accept packed sequences as inputs.

	Note:
	Instances of this class should never be created manually. They are meant
	to be instantiated by functions like :func:`pack_padded_sequence`.

	Batch sizes represent the number elements at each sequence step in
	the batch, not the varying sequence lengths passed to
	:func:`pack_padded_sequence`. For instance, given data ``abc`` and ``x``
	the :class:`PackedSequence` would contain data ``axbc`` with
	``batch_sizes=[2,1,1]``.

	Attributes:
	data (Tensor): Tensor containing packed sequence
	batch_sizes (Tensor): Tensor of integers holding
	information about the batch size at each sequence step
	sorted_indices (Tensor, optional): Tensor of integers holding how this
	:class:`PackedSequence` is constructed from sequences.
	unsorted_indices (Tensor, optional): Tensor of integers holding how this
	to recover the original sequences with correct order.

	.. note::
	:attr:`data` can be on arbitrary device and of arbitrary dtype.
	:attr:`sorted_indices` and :attr:`unsorted_indices` must be ``torch.int64``
	tensors on the same device as :attr:`data`.

	However, :attr:`batch_sizes` should always be a CPU ``torch.int64`` tensor.

	This invariant is maintained throughout :class:`PackedSequence` class,
	and all functions that construct a `:class:PackedSequence` in PyTorch
	(i.e., they only pass in tensors conforming to this constraint).

	"""
	def __new__(cls, data, batch_sizes=None, sorted_indices=None, unsorted_indices=None):
	return super(PackedSequence, cls).__new__(
	cls,
	*_packed_sequence_init_args(data, batch_sizes, sorted_indices,
	unsorted_indices))

	# NOTE [ device and dtype of a PackedSequence ]
	#
	# See the note above in doc string (starting with ":attr:`data` can be on
	# arbitrary device...").
	def pin_memory(self):
	# Why not convert `batch_sizes`?
	# See NOTE [ device and dtype of a PackedSequence ]
	return type(self)(self.data.pin_memory(), self.batch_sizes,
	bind(self.sorted_indices, lambda t: t.pin_memory()),
	bind(self.unsorted_indices, lambda t: t.pin_memory()))

	def cuda(self, args, *kwargs):
	# Tests to see if 'cuda' should be added to kwargs
	ex = torch.tensor((), dtype=self.data.dtype, device=self.data.device).to(args, *kwargs)
	if ex.is_cuda:
	return self.to(args, *kwargs)
	return self.to(args, device='cuda', *kwargs)

	def cpu(self, args, *kwargs):

	ex = torch.tensor((), dtype=self.data.dtype, device=self.data.device).to(args, *kwargs)
	if ex.device.type == 'cpu':
	return self.to(args, *kwargs)
	return self.to(args, device='cpu', *kwargs)

	def double(self):
	return self.to(dtype=torch.double)

	def float(self):
	return self.to(dtype=torch.float)

	def half(self):
	return self.to(dtype=torch.half)

	def long(self):
	return self.to(dtype=torch.long)

	def int(self):
	return self.to(dtype=torch.int)

	def short(self):
	return self.to(dtype=torch.short)

	def char(self):
	return self.to(dtype=torch.int8)

	def byte(self):
	return self.to(dtype=torch.uint8)

	def to(self, args, *kwargs):
	r"""Performs dtype and/or device conversion on `self.data`.

	It has similar signature as :meth:`torch.Tensor.to`, except optional
	arguments like `non_blocking` and `copy` should be passed as kwargs,
	not args, or they will not apply to the index tensors.

	.. note::

	If the ``self.data`` Tensor already has the correct :class:`torch.dtype`
	and :class:`torch.device`, then ``self`` is returned.
	Otherwise, returns a copy with the desired configuration.
	"""

	# Why not convert `batch_sizes`?
	# See NOTE [ device and dtype of a PackedSequence ]
	data = self.data.to(args, *kwargs)
	if data is self.data:
	return self
	else:
	# Does not forward device or dtype arg/kwargs, device is set from data.device
	kwargs = {k : v for k, v in filter(lambda t: t[0] != 'device' and t[0] != 'dtype', kwargs.items())}
	sorted_indices = bind(self.sorted_indices, lambda t: t.to(data.device, **kwargs))
	unsorted_indices = bind(self.unsorted_indices, lambda t: t.to(data.device, **kwargs))
	return type(self)(data, self.batch_sizes, sorted_indices, unsorted_indices)

	@property
	def is_cuda(self):
	r"""Returns true if `self.data` stored on a gpu"""
	return self.data.is_cuda

	def is_pinned(self):
	r"""Returns true if `self.data` stored on in pinned memory"""
	return self.data.is_pinned()


	# TorchScript doesn't support constructors on named tuples, so we use this helper
	# method to construct PackedSequence
	def _packed_sequence_init_args(data, batch_sizes=None, sorted_indices=None, unsorted_indices=None):
	# type: (Tensor, Optional[Tensor], Optional[Tensor], Optional[Tensor]) -> Tuple[Tensor, Tensor, Optional[Tensor], Optional[Tensor]] # noqa
	# NB: if unsorted_indices is provided, it should be the inverse permutation
	# to sorted_indices. Don't assert it here because the PackedSequence ctor
	# should only be used internally.

	if unsorted_indices is None:
	unsorted_indices = invert_permutation(sorted_indices)

	# support being called as `PackedSequence(data, batch_sizes, sorted_indices)`
	if batch_sizes is not None:
	# TODO: Re-enable this check (.type isn't supported in TorchScript)
	if batch_sizes.device.type != 'cpu':
	raise ValueError(
	"batch_sizes should always be on CPU. "
	"Instances of PackedSequence should never be created manually. "
	"They should be instantiated by functions like pack_sequence "
	"and pack_padded_sequences in nn.utils.rnn. "
	"https://pytorch.org/docs/stable/nn.html#torch.nn.utils.rnn.pack_sequence")
	return data, batch_sizes, sorted_indices, unsorted_indices

	# support being called as `PackedSequence((data, batch_sizes), *, sorted_indices)`
	else:
	assert isinstance(data, (list, tuple)) and len(data) == 2
	return data[0], data[1], sorted_indices, unsorted_indices


	def _packed_sequence_init(data, batch_sizes=None, sorted_indices=None, unsorted_indices=None):
	# type: (Tensor, Optional[Tensor], Optional[Tensor], Optional[Tensor]) -> PackedSequence
	data, batch_sizes, sorted_indices, unsorted_indices = _packed_sequence_init_args(
	data, batch_sizes, sorted_indices, unsorted_indices)
	return PackedSequence(data, batch_sizes, sorted_indices, unsorted_indices)


	def invert_permutation(permutation):
	# type: (Optional[Tensor]) -> Optional[Tensor]
	if permutation is None:
	return None
	output = torch.empty_like(permutation, memory_format=torch.legacy_contiguous_format)
	output.scatter_(0, permutation,
	torch.arange(0, permutation.numel(), device=permutation.device))
	return output


	def pack_padded_sequence(input, lengths, batch_first=False, enforce_sorted=True):
	# type: (Tensor, Tensor, bool, bool) -> PackedSequence
	r"""Packs a Tensor containing padded sequences of variable length.

	:attr:`input` can be of size ``T x B x *`` where `T` is the length of the
	longest sequence (equal to ``lengths[0]``), ``B`` is the batch size, and
	``*`` is any number of dimensions (including 0). If ``batch_first`` is
	``True``, ``B x T x *`` :attr:`input` is expected.

	For unsorted sequences, use `enforce_sorted = False`. If :attr:`enforce_sorted` is
	``True``, the sequences should be sorted by length in a decreasing order, i.e.
	``input[:,0]`` should be the longest sequence, and ``input[:,B-1]`` the shortest
	one. `enforce_sorted = True` is only necessary for ONNX export.

	Note:
	This function accepts any input that has at least two dimensions. You
	can apply it to pack the labels, and use the output of the RNN with
	them to compute the loss directly. A Tensor can be retrieved from
	a :class:`PackedSequence` object by accessing its ``.data`` attribute.

	Arguments:
	input (Tensor): padded batch of variable length sequences.
	lengths (Tensor): list of sequences lengths of each batch element.
	batch_first (bool, optional): if ``True``, the input is expected in ``B x T x *``
	format.
	enforce_sorted (bool, optional): if ``True``, the input is expected to
	contain sequences sorted by length in a decreasing order. If
	``False``, the input will get sorted unconditionally. Default: ``True``.

	Returns:
	a :class:`PackedSequence` object
	"""
	if torch._C._get_tracing_state() and not isinstance(lengths, torch.Tensor):
	warnings.warn('pack_padded_sequence has been called with a Python list of '
	'sequence lengths. The tracer cannot track the data flow of Python '
	'values, and it will treat them as constants, likely rendering '
	'the trace incorrect for any other combination of lengths.',
	stacklevel=2)
	lengths = torch.as_tensor(lengths, dtype=torch.int64)
	if enforce_sorted:
	sorted_indices = None
	else:
	lengths, sorted_indices = torch.sort(lengths, descending=True)
	sorted_indices = sorted_indices.to(input.device)
	batch_dim = 0 if batch_first else 1
	input = input.index_select(batch_dim, sorted_indices)

	data, batch_sizes = \
	_VF._pack_padded_sequence(input, lengths, batch_first)
	return _packed_sequence_init(data, batch_sizes, sorted_indices, None)


	def pad_packed_sequence(sequence, batch_first=False, padding_value=0.0, total_length=None):
	# type: (PackedSequence, bool, float, Optional[int]) -> Tuple[Tensor, Tensor]
	r"""Pads a packed batch of variable length sequences.

	It is an inverse operation to :func:`pack_padded_sequence`.

	The returned Tensor's data will be of size ``T x B x *``, where `T` is the length
	of the longest sequence and `B` is the batch size. If ``batch_first`` is True,
	the data will be transposed into ``B x T x *`` format.

	Example:
	>>> from torch.nn.utils.rnn import pack_padded_sequence, pad_packed_sequence
	>>> seq = torch.tensor([[1,2,0], [3,0,0], [4,5,6]])
	>>> lens = [2, 1, 3]
	>>> packed = pack_padded_sequence(seq, lens, batch_first=True, enforce_sorted=False)
	>>> packed
	PackedSequence(data=tensor([4, 1, 3, 5, 2, 6]), batch_sizes=tensor([3, 2, 1]),
	sorted_indices=tensor([2, 0, 1]), unsorted_indices=tensor([1, 2, 0]))
	>>> seq_unpacked, lens_unpacked = pad_packed_sequence(packed, batch_first=True)
	>>> seq_unpacked
	tensor([[1, 2, 0],
	[3, 0, 0],
	[4, 5, 6]])
	>>> lens_unpacked
	tensor([2, 1, 3])

	.. note::
	:attr:`total_length` is useful to implement the
	``pack sequence -> recurrent network -> unpack sequence`` pattern in a
	:class:`~torch.nn.Module` wrapped in :class:`~torch.nn.DataParallel`.
	See :ref:`this FAQ section <pack-rnn-unpack-with-data-parallelism>` for
	details.

	Arguments:
	sequence (PackedSequence): batch to pad
	batch_first (bool, optional): if ``True``, the output will be in ``B x T x *``
	format.
	padding_value (float, optional): values for padded elements.
	total_length (int, optional): if not ``None``, the output will be padded to
	have length :attr:`total_length`. This method will throw :class:`ValueError`
	if :attr:`total_length` is less than the max sequence length in
	:attr:`sequence`.

	Returns:
	Tuple of Tensor containing the padded sequence, and a Tensor
	containing the list of lengths of each sequence in the batch.
	Batch elements will be re-ordered as they were ordered originally when
	the batch was passed to ``pack_padded_sequence`` or ``pack_sequence``.




	"""
	max_seq_length = sequence.batch_sizes.size(0)
	if total_length is not None:
	if total_length < max_seq_length:
	raise ValueError("Expected total_length to be at least the length "
	"of the longest sequence in input, but got "
	"total_length={} and max sequence length being {}"
	.format(total_length, max_seq_length))
	max_seq_length = total_length
	padded_output, lengths = _VF._pad_packed_sequence(
	sequence.data, sequence.batch_sizes, batch_first, padding_value, max_seq_length)
	unsorted_indices = sequence.unsorted_indices
	if unsorted_indices is not None:
	batch_dim = 0 if batch_first else 1
	return padded_output.index_select(batch_dim, unsorted_indices), lengths[unsorted_indices]
	return padded_output, lengths


	def pad_sequence(sequences, batch_first=False, padding_value=0):
	r"""Pad a list of variable length Tensors with ``padding_value``

	``pad_sequence`` stacks a list of Tensors along a new dimension,
	and pads them to equal length. For example, if the input is list of
	sequences with size ``L x `` and if batch_first is False, and ``T x B x ``
	otherwise.

	`B` is batch size. It is equal to the number of elements in ``sequences``.
	`T` is length of the longest sequence.
	`L` is length of the sequence.
	`*` is any number of trailing dimensions, including none.

	Example:
	>>> from torch.nn.utils.rnn import pad_sequence
	>>> a = torch.ones(25, 300)
	>>> b = torch.ones(22, 300)
	>>> c = torch.ones(15, 300)
	>>> pad_sequence([a, b, c]).size()
	torch.Size([25, 3, 300])

	Note:
	This function returns a Tensor of size ``T x B x `` or ``B x T x ``
	where `T` is the length of the longest sequence. This function assumes
	trailing dimensions and type of all the Tensors in sequences are same.

	Arguments:
	sequences (list[Tensor]): list of variable length sequences.
	batch_first (bool, optional): output will be in ``B x T x *`` if True, or in
	``T x B x *`` otherwise
	padding_value (float, optional): value for padded elements. Default: 0.

	Returns:
	Tensor of size ``T x B x *`` if :attr:`batch_first` is ``False``.
	Tensor of size ``B x T x *`` otherwise
	"""

	# assuming trailing dimensions and type of all the Tensors
	# in sequences are same and fetching those from sequences[0]
	max_size = sequences[0].size()
	trailing_dims = max_size[1:]
	max_len = max([s.size(0) for s in sequences])
	if batch_first:
	out_dims = (len(sequences), max_len) + trailing_dims
	else:
	out_dims = (max_len, len(sequences)) + trailing_dims

	out_tensor = sequences[0].data.new(*out_dims).fill_(padding_value)
	for i, tensor in enumerate(sequences):
	length = tensor.size(0)
	# use index notation to prevent duplicate references to the tensor
	if batch_first:
	out_tensor[i, :length, ...] = tensor
	else:
	out_tensor[:length, i, ...] = tensor

	return out_tensor


	def pack_sequence(sequences, enforce_sorted=True):
	# type: (List[Tensor], bool) -> PackedSequence
	r"""Packs a list of variable length Tensors

	``sequences`` should be a list of Tensors of size ``L x *``, where `L` is
	the length of a sequence and `*` is any number of trailing dimensions,
	including zero.

	For unsorted sequences, use `enforce_sorted = False`. If ``enforce_sorted``
	is ``True``, the sequences should be sorted in the order of decreasing length.
	``enforce_sorted = True`` is only necessary for ONNX export.


	Example:
	>>> from torch.nn.utils.rnn import pack_sequence
	>>> a = torch.tensor([1,2,3])
	>>> b = torch.tensor([4,5])
	>>> c = torch.tensor([6])
	>>> pack_sequence([a, b, c])
	PackedSequence(data=tensor([ 1, 4, 6, 2, 5, 3]), batch_sizes=tensor([ 3, 2, 1]))


	Arguments:
	sequences (list[Tensor]): A list of sequences of decreasing length.
	enforce_sorted (bool, optional): if ``True``, checks that the input
	contains sequences sorted by length in a decreasing order. If
	``False``, this condition is not checked. Default: ``True``.

	Returns:
	a :class:`PackedSequence` object
	"""
	lengths = [v.size(0) for v in sequences]
	return pack_padded_sequence(pad_sequence(sequences), lengths, enforce_sorted=enforce_sorted)