tensorset is a pytorch library that lets you perform operations on related sequences using a unified TensorSet object.
It aims to reduce the complexity of using multiple related sequences. Sequences like these are very commonly used as inputs to a transformer model:
import torch
from torch import nn
batch_size = 8
sequence_length = 1024
vocab_size = 256
hidden_size = 768
pad_id = 255
token_embeddings = nn.Embedding(vocab_size, hidden_size)
input_ids = torch.randint(0, vocab_size, (batch_size, sequence_length))
input_embeds = token_embeddings(input_ids) # Shape: batch_size, sequence_length, hidden_size
key_pad_mask = input_ids == pad_id # Shape: batch_size, sequence_length
is_whitespace_mask = (input_ids == 0) | (input_ids == 1)# Shape: batch_size, sequence_length
# These tensors would be used like this:
# logits = transformer_model(input_embeds, key_pad_mask, is_whitespace_mask)Notice wherever these tensors are truncated or stacked or concatenated there will be tedious repetitive code like this:
def truncate_inputs(input_ids, key_pad_mask, is_whitespace_mask, length):
input_ids= input_ids[:, :length]
key_pad_mask= key_pad_mask[:, :length]
is_whitespace_mask= is_whitespace_mask[:, :length]
return input_ids, key_pad_mask, is_whitespace_mask
truncated_inputs = truncate_inputs(input_ids, key_pad_mask, is_whitespace_mask, length=10)This repetitive code can be avoided. input_ids, input_embeds, key_pad_mask, and is_whitespace_mask are all related.
They all have matching leading dimensions for batch_size and sequence length.
TensorSet is a container for these related multi-dimensional sequences, making this kind of manipulation very easy and ergonomic.
import tensorset as ts
length = 10
inputs = ts.TensorSet(
input_ids=input_ids,
input_embeds=input_embeds,
key_pad_mask=key_pad_mask,
is_whitespace_mask=is_whitespace_mask,
)
truncated_inputs = inputs.iloc[:, :length]
print(truncated_inputs)prints:
TensorSet(
named_columns:
name: input_ids, shape: torch.Size([8, 10]), dtype: torch.int64
name: input_embeds, shape: torch.Size([8, 10, 768]), dtype: torch.float32
name: key_pad_mask, shape: torch.Size([8, 10]), dtype: torch.bool
name: is_whitespace_mask, shape: torch.Size([8, 10]), dtype: torch.bool
)
Stack related TensorSets to create larger batches
sequence_length = 20
sequence_1 = ts.TensorSet(
torch.randn(sequence_length, 512),
torch.randn(sequence_length, 1024),
)
sequence_2 = ts.TensorSet(
torch.randn(sequence_length, 512),
torch.randn(sequence_length, 1024),
)
batch = ts.stack((sequence_1, sequence_2), 0)
print(batch.size(1)) # This is the sequence length, prints 20
print(batch.size(0)) # This is the batch size, prints 2Pad TensorSets with a specific amount of padding along the sequence dimension
sequence_length = 20
sequence = ts.TensorSet(
torch.randn(sequence_length, 512),
torch.randn(sequence_length, 1024),
)
pad_value = -200
padded_sequence = sequence.pad(44, 0, pad_value) # add 44 dims of padding along dimension 0, of pad_value
print(padded_sequence.size(0)) # This is the new sequence length, prints 64Stack TensorSets with irregular shape, using torch.nested
# C, H, W pixel_values, and an additional binary mask
image1 = ts.TensorSet(
pixel_values = torch.randn(3, 20, 305),
mask = torch.randn(3, 20, 305) > 0,
)
image2 = ts.TensorSet(
pixel_values = torch.randn(3, 450, 200),
mask = torch.randn(3, 450, 200) > 0,
)
images = ts.stack_nt([image1, image2])
print(images)output:
TensorSet(
named_columns:
name: pixel_values, shape: nested_tensor.Size([2, 3, irregular, irregular]), dtype: torch.float32
name: mask, shape: nested_tensor.Size([2, 3, irregular, irregular]), dtype: torch.bool
)
- Access by lists of columns
- Enable operations over irregular dims that are not supported yet by torch.nested, such as mean and index select
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