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_utils.py
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_utils.py
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import torch
import warnings
from collections import defaultdict
def _type(self, dtype=None, non_blocking=False, **kwargs):
"""Returns the type if `dtype` is not provided, else casts this object to
the specified type.
If this is already of the correct type, no copy is performed and the
original object is returned.
Args:
dtype (type or string): The desired type
non_blocking (bool): If ``True``, and the source is in pinned memory
and destination is on the GPU or vice versa, the copy is performed
asynchronously with respect to the host. Otherwise, the argument
has no effect.
**kwargs: For compatibility, may contain the key ``async`` in place of
the ``non_blocking`` argument. The ``async`` arg is deprecated.
"""
non_blocking = _get_async_or_non_blocking('type', non_blocking, kwargs)
if dtype is None:
return self.__module__ + '.' + self.__class__.__name__
if isinstance(dtype, str):
dtype = _import_dotted_name(dtype)
if dtype == type(self):
return self
if self.is_sparse:
if not dtype.is_sparse:
raise RuntimeError("Cannot cast sparse tensor to dense tensor")
new_module_name = dtype.__module__.replace('.sparse', '')
new_values_type_name = new_module_name + '.' + dtype.__name__
new_values = torch._values(self).type(new_values_type_name, non_blocking)
new_indices_type_name = new_module_name + '.LongTensor'
new_indices = torch._indices(self).type(new_indices_type_name, non_blocking)
return dtype(new_indices, new_values, self.size())
if dtype.is_sparse:
raise RuntimeError("Cannot cast dense tensor to sparse tensor")
return dtype(self.size()).copy_(self, non_blocking)
def _cuda(self, device=None, non_blocking=False, **kwargs):
"""Returns a copy of this object in CUDA memory.
If this object is already in CUDA memory and on the correct device, then
no copy is performed and the original object is returned.
Args:
device (int): The destination GPU id. Defaults to the current device.
non_blocking (bool): If ``True`` and the source is in pinned memory,
the copy will be asynchronous with respect to the host. Otherwise,
the argument has no effect.
**kwargs: For compatibility, may contain the key ``async`` in place of
the ``non_blocking`` argument.
"""
non_blocking = _get_async_or_non_blocking('cuda', non_blocking, kwargs)
if self.is_cuda:
if device is None:
device = torch.cuda.current_device()
if self.get_device() == device:
return self
else:
if device is None:
device = -1
with torch.cuda.device(device):
if self.is_sparse:
new_type = getattr(torch.cuda.sparse, self.__class__.__name__)
indices = torch._indices(self).cuda(device, non_blocking)
values = torch._values(self).cuda(device, non_blocking)
return new_type(indices, values, self.size())
else:
new_type = getattr(torch.cuda, self.__class__.__name__)
return new_type(self.size()).copy_(self, non_blocking)
def _get_async_or_non_blocking(function_name, non_blocking, kwargs):
if not kwargs:
return non_blocking
if len(kwargs) != 1 or 'async' not in kwargs:
message = "{}() got an unexpected keyword argument '{}'"
argument = list(kwargs.keys()).pop()
raise TypeError(message.format(function_name, argument))
warnings.warn("'async' is deprecated; use 'non_blocking'")
return kwargs['async']
# Note [Don't serialize hooks]
# ~~~~~~~~~~~~~~~~~~~~~~~~~~~~
# Since time immemorial, we have serialized the backward hooks associated with
# variables. This kind of half-worked--Python can pickle global functions
# (but not closures!)--but there were problems.
#
# - It's fragile. If you serialize a backward hook into a saved
# model, and then you rename the function associated with the hook,
# now your saved model is broken and you can't load it anymore.
#
# - It's not actually used. The standard recommendation is to
# serialize the *state_dict* of a model, not the model itself
# (since this is more stable to code changes affecting the model
# serialization), and the state dict saves "data" only, thus
# stripping the the backward hooks. In some cases, hooks are
# essential to the well-functioning of a model (e.g., DDP),
# but DDP already manages readding the hooks!
#
# - We didn't serialize them in many cases. Prior to #10220, we
# were dropping backward hooks in ForkingPickler. We "fixed" this
# to be convenient with other serialization sites, but lack of
# serializing backward hooks wasn't actually the root cause of
# the bug.
#
# With these cases in mind, we have decided that a better strategy
# is to just NOT serialize hooks at all.
#
# Since this is a BC-breaking change, we should warn when we previously
# serialized a hook, but no longer do so. This will be done by adding a special
# sentinel property to hooks will be used to suppress this warning. If a hook
# has the property _torch_serialize_ignore, we will not emit a warning if we
# attempt to serialize a Tensor with this hook attached to it.
#
# By the way, when _backward_hooks is skipped, we must give an EMPTY
# OrderedDict(), if you pass a None you'll run afoul #12219.
def _rebuild_tensor(storage, storage_offset, size, stride):
# first construct a tensor with the correct dtype/device
t = torch.tensor([], dtype=storage.dtype, device=storage.device)
return t.set_(storage, storage_offset, size, stride)
def _rebuild_tensor_v2(storage, storage_offset, size, stride, requires_grad, backward_hooks):
tensor = _rebuild_tensor(storage, storage_offset, size, stride)
tensor.requires_grad = requires_grad
# NB: This line exists only for backwards compatibility; the
# general expectation is that backward_hooks is an empty
# OrderedDict. See Note [Don't serialize hooks]
tensor._backward_hooks = backward_hooks
return tensor
def _rebuild_parameter(data, requires_grad, backward_hooks):
param = torch.nn.Parameter(data, requires_grad)
# NB: This line exists only for backwards compatibility; the
# general expectation is that backward_hooks is an empty
# OrderedDict. See Note [Don't serialize hooks]
param._backward_hooks = backward_hooks
return param
def _import_dotted_name(name):
components = name.split('.')
obj = __import__(components[0])
for component in components[1:]:
obj = getattr(obj, component)
return obj
# Taken from python 3.5 docs
def _accumulate(iterable, fn=lambda x, y: x + y):
'Return running totals'
# _accumulate([1,2,3,4,5]) --> 1 3 6 10 15
# _accumulate([1,2,3,4,5], operator.mul) --> 1 2 6 24 120
it = iter(iterable)
try:
total = next(it)
except StopIteration:
return
yield total
for element in it:
total = fn(total, element)
yield total
def _flatten_dense_tensors(tensors):
"""Flatten dense tensors into a contiguous 1D buffer. Assume tensors are of
same dense type.
Since inputs are dense, the resulting tensor will be a concatenated 1D
buffer. Element-wise operation on this buffer will be equivalent to
operating individually.
Arguments:
tensors (Iterable[Tensor]): dense tensors to flatten.
Returns:
A contiguous 1D buffer containing input tensors.
"""
if len(tensors) == 1:
return tensors[0].contiguous().view(-1)
flat = torch.cat([t.contiguous().view(-1) for t in tensors], dim=0)
return flat
def _flatten_sparse_tensors(tensors):
"""Flatten sparse tensors into two contiguous 1D buffers, one of indices and
one of values. Assume tensors are of same sparse type.
Arguments:
tensors (Iterable[Tensor]): sparse tensors to flatten.
Returns:
A tuple of two contiguous 1D buffers, one containing input tensors'
indices and the other containing the values.
"""
flat_indices = _flatten_dense_tensors([torch._indices(t) for t in tensors])
flat_values = _flatten_dense_tensors([torch._values(t) for t in tensors])
return flat_indices, flat_values
def _unflatten_dense_tensors(flat, tensors):
"""View a flat buffer using the sizes of tensors. Assume that tensors are of
same dense type, and that flat is given by _flatten_dense_tensors.
Arguments:
flat (Tensor): flattened dense tensors to unflatten.
tensors (Iterable[Tensor]): dense tensors whose sizes will be used to
unflatten flat.
Returns:
Unflattened dense tensors with sizes same as tensors and values from
flat.
"""
outputs = []
offset = 0
for tensor in tensors:
numel = tensor.numel()
outputs.append(flat.narrow(0, offset, numel).view_as(tensor))
offset += numel
return tuple(outputs)
def _unflatten_sparse_tensors(flat, tensors):
"""View flat buffer (containing indices and values) using the sizes of
tensors. Assume that tensors are of same sparse type, and that flat is given
by _flatten_sparse_tensors.
Arguments:
flat (tuple(Tensor, Tensor)): flattened indices and values of sparse
tensors to unflatten.
tensors (Iterable[Tensor]): sparse tensors whose sizes will be used to
unflatten flat.
Returns:
Unflattened sparse tensors with sizes same as tensors and values from
flat.
"""
flat_indices, flat_values = flat
indices = _unflatten_dense_tensors(flat_indices, [torch._indices(t) for t in tensors])
values = _unflatten_dense_tensors(flat_values, [torch._values(t) for t in tensors])
outputs = []
for t, i, v in zip(tensors, indices, values):
outputs.append(t.new(i, v, t.size()))
return tuple(outputs)
def _reorder_tensors_as(tensors, ordered_tensors):
"""Assume that tensors are of same order as ordered_tensors within their
types, e.g., from _take_tensors. Reorder them to be of same order as
ordered_tensors.
Arguments:
tensors (Iterable[Tensor]): tensors to be reordered. They should be of
the same order as ordered_tensors within their own types.
ordered_tensors (Iterable[Tensor]): tensors whose order will be the
reference.
Returns:
Ordered tuple of tensors with contents from tensors and order of
ordered_tensors.
"""
type_dict = defaultdict(list)
for tensor in tensors:
type_dict[tensor.type()].append(tensor)
type_dict = {t: iter(coll) for t, coll in type_dict.items()}
return tuple(next(type_dict[tensor.type()]) for tensor in ordered_tensors)
def _take_tensors(tensors, size_limit):
"""Group tensors into chunks. This generator yields a chunk at each time,
each containing tensors of same type up to certain byte limit in total size.
Args:
tensors (Sequence): A sequence of tensors to be separated into chunks.
size_limit (int): The limit of each chunk in bytes.
Yields:
Blocks of tensors of same type and within size_limit. The yielded
tensors are only ordered as the original sequence within its types.
"""
buf_dict = defaultdict(lambda: [[], 0])
for tensor in tensors:
t = tensor.type()
if tensor.is_sparse:
indices = torch._indices(tensor)
values = torch._values(tensor)
size = indices.numel() * indices.element_size() + values.numel() * values.element_size()
else:
size = tensor.numel() * tensor.element_size()
buf_and_size = buf_dict[t]
if buf_and_size[1] + size > size_limit and buf_and_size[1] > 0:
yield buf_and_size[0]
buf_and_size = buf_dict[t] = [[], 0]
buf_and_size[0].append(tensor)
buf_and_size[1] += size
for buf, _ in buf_dict.values():
if len(buf) > 0:
yield buf
# annotation decorator to get annotations in a way that is compatible
# with both Python 2 and 3
def annotate(ret, **kwargs):
def dec(fun):
fun.__annotations__ = dict(kwargs)
fun.__annotations__['return'] = ret
return fun
return dec