This draft implementation should now be considered completed. If you are interested in using Named Tensor check out the core PyTorch implementation:
https://pytorch.org/docs/stable/named_tensor.html
Thanks for everyone who contributed to this version.
A proposal for a named tensor for Torch described here:
http://nlp.seas.harvard.edu/NamedTensor
NamedTensor is an thin-wrapper on Torch tensor that makes three changes to the API:
- Naming: Dimension access and reduction use a named
dim
argument instead of an index. Constructing and adding dimensions use aname
argument. Axis-based indexing [ ] is replaced by named indexing. - Broadcasting: All functions broadcast based on set-operations not through heuristic ordering rules, e.g. if
z = x + y
thenz
has the union of the dimension inx
andy
. - Lifting: Order-based functions can be lifted by providing name annotations through
.spec
methods. For instance, convolution requires the user to name the channel and kernel dims, e.g .conv2d.spec("channel", ("x", "y"))
. This provides dynamic checks, better error messages, and consistent documentation.
pip install git+https://github.com/harvardnlp/namedtensor
from namedtensor import ntorch
All pytorch builders have an extra keyword argument names.
x = ntorch.randn(10, 10, 20, names=("batch", "h", "w"))
x = ntorch.ones(10, 10, 20, names=("batch", "h", "w"))
All functions that keep dimensionality work in the same way.
x = x.log()
x = x.float()
x = ntorch.exp(x)
Indexing and masking operation work by name as opposed to absolute position.
first_batch = x[{"batch": 1}]
three_examples = x[{"batch": slice(1, 4)}]
masked = x[ x > 0.5 ]
Advanced indexing by named tensors.
select = ntorch.tensor([1, 4, 5], names=("rows",))
y = x[{"h": select}]
# y shape ("batch", "rows", "w")
View, tranpose, and friends are deprecated in favor of named access and movement.
x = x.stack(("w", "h"), "stackdim")
# Roundtrip
x = x.split("stackdim", ("w", "h"), w=20)
There is no need to ever have unsqueeze since broadcasting is done by name overlap.
Similar notation can be used for setting values.
Any function with a dim
argument now can be accessed based on the
dimension name.
x = x.narrow("w", 0, 10)
x = x.softmax("w")
This is true of reductions functions as well, where the named dimension is eliminated.
x = x.mean("w")
x, argmax = x.max("w")
Matrix operations also use the dimension arguments. We can replace einsum based on persistent names.
x = ntorch.randn(10, 10, 20, names=("batch", "h", "w"))
y = ntorch.randn(10, 20, 30, names=("batch", "w", "c"))
x.dot("w", y)
This also makes indexing much easier to read.
x = ntorch.ones(10, 10, 20, names=("batch", "time", "vocab"))
y = ntorch.randn(20, 30, names=("vocab", "embsize"))
y.index_select("vocab", x)
The following functions are removed from the stdlib.
- view, expand, squeeze, unsqueeze, transpose
NN units no longer take ordered tensors. They now have a required additional method spec
that lets the user set the the input and output dimensions of the object.
Examples
conv = ntorch.nn.Conv1d(5, 10, 2).spec("input", "time", "output")
n = ntorch.randn(20, 30, 5, names=("batch", "time", "input"))
out = conv(n)
drop = ntorch.nn.Dropout()
n = ntorch.randn(4, 20, names=("batch", "target"))
out = drop(n)
loss = ntorch.nn.NLLLoss().spec("target")
predict = ntorch.randn(20, 4, names=("target", "batch"))
target = ntorch.tensor([2, 2, 3, 4], names=("batch",))
out = loss(predict, target)
# Univariate
mu = ntorch.randn(10, names=("batch"))
sigma = ntorch.randn(10, names=("batch"))
dist = ntorch.distributions.Normal(mu, sigma)
sample = dist.sample((30, 40), names=("sample1", "sample2"))
# Discrete
params = ntorch.randn(10, 20, 30, names=("batch1", "batch2", "logits"))
dist = ntorch.distributions.Categorical(logits=params, logit_dim="logits")
http://nlp.seas.harvard.edu/namedtensor/
- Alexander Rush ([email protected], @harvardnlp)
(NamedTensor is being collectively developed by Harvard CS 287)
- Yuntian Deng
- Justin Chiu
- Francisco Rivera
- Jiafeng Chen
- Celine Liang
- Miro Furtado
- Roshan Padaki
- Mirac Suzgun
- Belén Saldías
- Jason Ren
- Josh Feldman
- Jambay Kinley
- Ian Kivlichan
- Sanyuan Chen
- Simon Shen