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r""""Contains definitions of the methods used by the _BaseDataLoaderIter workers to
collate samples fetched from dataset into Tensor(s).
These **needs** to be in global scope since Py2 doesn't support serializing
static methods.
`default_collate` and `default_convert` are exposed to users via 'dataloader.py'.
"""
import torch
import re
import collections
from torch._six import string_classes
np_str_obj_array_pattern = re.compile(r'[SaUO]')
def default_convert(data):
r"""
Function that converts each NumPy array element into a :class:`torch.Tensor`. If the input is a `Sequence`,
`Collection`, or `Mapping`, it tries to convert each element inside to a :class:`torch.Tensor`.
If the input is not an NumPy array, it is left unchanged.
This is used as the default function for collation when both `batch_sampler` and
`batch_size` are NOT defined in :class:`~torch.utils.data.DataLoader`.
The general input type to output type mapping is similar to that
of :func:`~torch.utils.data.default_collate`. See the description there for more details.
Args:
data: a single data point to be converted
Examples:
>>> # Example with `int`
>>> default_convert(0)
0
>>> # Example with NumPy array
>>> # xdoctest: +SKIP
>>> default_convert(np.array([0, 1]))
tensor([0, 1])
>>> # Example with NamedTuple
>>> Point = namedtuple('Point', ['x', 'y'])
>>> default_convert(Point(0, 0))
Point(x=0, y=0)
>>> default_convert(Point(np.array(0), np.array(0)))
Point(x=tensor(0), y=tensor(0))
>>> # Example with List
>>> default_convert([np.array([0, 1]), np.array([2, 3])])
[tensor([0, 1]), tensor([2, 3])]
"""
elem_type = type(data)
if isinstance(data, torch.Tensor):
return data
elif elem_type.__module__ == 'numpy' and elem_type.__name__ != 'str_' \
and elem_type.__name__ != 'string_':
# array of string classes and object
if elem_type.__name__ == 'ndarray' \
and np_str_obj_array_pattern.search(data.dtype.str) is not None:
return data
return torch.as_tensor(data)
elif isinstance(data, collections.abc.Mapping):
try:
return elem_type({key: default_convert(data[key]) for key in data})
except TypeError:
# The mapping type may not support `__init__(iterable)`.
return {key: default_convert(data[key]) for key in data}
elif isinstance(data, tuple) and hasattr(data, '_fields'): # namedtuple
return elem_type(*(default_convert(d) for d in data))
elif isinstance(data, tuple):
return [default_convert(d) for d in data] # Backwards compatibility.
elif isinstance(data, collections.abc.Sequence) and not isinstance(data, string_classes):
try:
return elem_type([default_convert(d) for d in data])
except TypeError:
# The sequence type may not support `__init__(iterable)` (e.g., `range`).
return [default_convert(d) for d in data]
else:
return data
default_collate_err_msg_format = (
"default_collate: batch must contain tensors, numpy arrays, numbers, "
"dicts or lists; found {}")
def default_collate(batch):
r"""
Function that takes in a batch of data and puts the elements within the batch
into a tensor with an additional outer dimension - batch size. The exact output type can be
a :class:`torch.Tensor`, a `Sequence` of :class:`torch.Tensor`, a
Collection of :class:`torch.Tensor`, or left unchanged, depending on the input type.
This is used as the default function for collation when
`batch_size` or `batch_sampler` is defined in :class:`~torch.utils.data.DataLoader`.
Here is the general input type (based on the type of the element within the batch) to output type mapping:
* :class:`torch.Tensor` -> :class:`torch.Tensor` (with an added outer dimension batch size)
* NumPy Arrays -> :class:`torch.Tensor`
* `float` -> :class:`torch.Tensor`
* `int` -> :class:`torch.Tensor`
* `str` -> `str` (unchanged)
* `bytes` -> `bytes` (unchanged)
* `Mapping[K, V_i]` -> `Mapping[K, default_collate([V_1, V_2, ...])]`
* `NamedTuple[V1_i, V2_i, ...]` -> `NamedTuple[default_collate([V1_1, V1_2, ...]),
default_collate([V2_1, V2_2, ...]), ...]`
* `Sequence[V1_i, V2_i, ...]` -> `Sequence[default_collate([V1_1, V1_2, ...]),
default_collate([V2_1, V2_2, ...]), ...]`
Args:
batch: a single batch to be collated
Examples:
>>> # Example with a batch of `int`s:
>>> default_collate([0, 1, 2, 3])
tensor([0, 1, 2, 3])
>>> # Example with a batch of `str`s:
>>> default_collate(['a', 'b', 'c'])
['a', 'b', 'c']
>>> # Example with `Map` inside the batch:
>>> default_collate([{'A': 0, 'B': 1}, {'A': 100, 'B': 100}])
{'A': tensor([ 0, 100]), 'B': tensor([ 1, 100])}
>>> # Example with `NamedTuple` inside the batch:
>>> # xdoctest: +SKIP
>>> Point = namedtuple('Point', ['x', 'y'])
>>> default_collate([Point(0, 0), Point(1, 1)])
Point(x=tensor([0, 1]), y=tensor([0, 1]))
>>> # Example with `Tuple` inside the batch:
>>> default_collate([(0, 1), (2, 3)])
[tensor([0, 2]), tensor([1, 3])]
>>> # Example with `List` inside the batch:
>>> default_collate([[0, 1], [2, 3]])
[tensor([0, 2]), tensor([1, 3])]
"""
elem = batch[0]
elem_type = type(elem)
if isinstance(elem, torch.Tensor):
out = None
if torch.utils.data.get_worker_info() is not None:
# If we're in a background process, concatenate directly into a
# shared memory tensor to avoid an extra copy
numel = sum(x.numel() for x in batch)
storage = elem.storage()._new_shared(numel, device=elem.device)
out = elem.new(storage).resize_(len(batch), *list(elem.size()))
return torch.stack(batch, 0, out=out)
elif elem_type.__module__ == 'numpy' and elem_type.__name__ != 'str_' \
and elem_type.__name__ != 'string_':
if elem_type.__name__ == 'ndarray' or elem_type.__name__ == 'memmap':
# array of string classes and object
if np_str_obj_array_pattern.search(elem.dtype.str) is not None:
raise TypeError(default_collate_err_msg_format.format(elem.dtype))
return default_collate([torch.as_tensor(b) for b in batch])
elif elem.shape == (): # scalars
return torch.as_tensor(batch)
elif isinstance(elem, float):
return torch.tensor(batch, dtype=torch.float64)
elif isinstance(elem, int):
return torch.tensor(batch)
elif isinstance(elem, string_classes):
return batch
elif isinstance(elem, collections.abc.Mapping):
try:
return elem_type({key: default_collate([d[key] for d in batch]) for key in elem})
except TypeError:
# The mapping type may not support `__init__(iterable)`.
return {key: default_collate([d[key] for d in batch]) for key in elem}
elif isinstance(elem, tuple) and hasattr(elem, '_fields'): # namedtuple
return elem_type(*(default_collate(samples) for samples in zip(*batch)))
elif isinstance(elem, collections.abc.Sequence):
# check to make sure that the elements in batch have consistent size
it = iter(batch)
elem_size = len(next(it))
if not all(len(elem) == elem_size for elem in it):
raise RuntimeError('each element in list of batch should be of equal size')
transposed = list(zip(*batch)) # It may be accessed twice, so we use a list.
if isinstance(elem, tuple):
return [default_collate(samples) for samples in transposed] # Backwards compatibility.
else:
try:
return elem_type([default_collate(samples) for samples in transposed])
except TypeError:
# The sequence type may not support `__init__(iterable)` (e.g., `range`).
return [default_collate(samples) for samples in transposed]
raise TypeError(default_collate_err_msg_format.format(elem_type)) |