Frame-based semantic parsing library trained on FrameNet and built on HuggingFace's T5 Transformer
Live Demo: chanind.github.io/frame-semantic-transformer
Full docs: frame-semantic-transformer.readthedocs.io
This library draws heavily on Open-Sesame (paper) for inspiration on training and evaluation on FrameNet 1.7, and uses ideas from the paper Open-Domain Frame Semantic Parsing Using Transformers for using T5 as a frame-semantic parser. SimpleT5 was also used as a base for the initial training setup.
More details: FrameNet Parsing with Transformers Blog Post
This library uses the same train/dev/test documents and evaluation methodology as Open-Sesame, so that the results should be comparable between the 2 libraries. There are 2 pretrained models available, base
and small
, corresponding to t5-base
and t5-small
in Huggingface, respectively.
Task | Sesame F1 (dev/test) | Small Model F1 (dev/test) | Base Model F1 (dev/test) |
---|---|---|---|
Trigger identification | 0.80 / 0.73 | 0.75 / 0.71 | 0.78 / 0.74 |
Frame classification | 0.90 / 0.87 | 0.87 / 0.86 | 0.91 / 0.89 |
Argument extraction | 0.61 / 0.61 | 0.76 / 0.73 | 0.78 / 0.75 |
The base model performs similarly to Open-Sesame on trigger identification and frame classification tasks, but outperforms it by a significant margin on argument extraction. The small pretrained model has lower F1 than base across the board, but is 1/4 the size and still outperforms Open-Sesame at argument extraction.
pip install frame-semantic-transformer
The main entry to interacting with the library is the FrameSemanticTransformer
class, as shown below. For inference the detect_frames()
method is likely all that is needed to perform frame parsing.
from frame_semantic_transformer import FrameSemanticTransformer
frame_transformer = FrameSemanticTransformer()
result = frame_transformer.detect_frames("The hallway smelt of boiled cabbage and old rag mats.")
print(f"Results found in: {result.sentence}")
for frame in result.frames:
print(f"FRAME: {frame.name}")
for element in frame.frame_elements:
print(f"{element.name}: {element.text}")
The result returned from detect_frames()
is an object containing sentence
, a parsed version of the original sentence text, trigger_locations
, the indices within the sentence where frame triggers were detected, and frames
, a list of all detected frames in the sentence. Within frames
, each object containes name
which corresponds to the FrameNet name of the frame, trigger_location
corresponding to which trigger in the text this frame this frame uses, and frame_elements
containing a list of all relevant frame elements found in the text.
For more efficient bulk processing of text, there's a detect_frames_bulk
method which will process a list of sentences in batches. You can control the batch size using the batch_size
param. By default this is 8
.
frame_transformer = FrameSemanticTransformer(batch_size=16)
result = frame_transformer.detect_frames_bulk([
"I'm getting quite hungry, but I can wait a bit longer.",
"The chef gave the food to the customer.",
"The hallway smelt of boiled cabbage and old rag mats.",
])
Note: It's not recommended to pass more than a single sentence per string to detect_frames()
or detect_frames_bulk()
. If you have a paragraph of text to process, it's best to split the paragraph into a list of sentences and pass the sentences as a list to detect_frames_bulk()
. Only single sentences per string were used during training, so it's not clear how the model will handle multiple sentences in the same string.
# ❌ Bad, don't do this
frame_transformer.detect_frames("Fuzzy Wuzzy was a bear. Fuzzy Wuzzy had no hair.")
# 👍 Do this instead
frame_transformer.detect_frames_bulk([
"Fuzzy Wuzzy was a bear.",
"Fuzzy Wuzzy had no hair.",
])
By default, FrameSemanticTransformer
will attempt to use a GPU if one is available. If you'd like to explictly set whether to run on GPU vs CPU, you can pass the use_gpu
param.
# force the model to run on the CPU
frame_transformer = FrameSemanticTransformer(use_gpu=False)
There are currently 2 available pre-trained models for inference, called base
and small
, fine-tuned from HuggingFace's t5-base and t5-small model respectively. If a local fine-tuned t5 model exists that can be loaded as well. If no model is specified, the base
model will be used.
base_transformer = FrameSemanticTransformer("base") # this is also the default
small_transformer = FrameSemanticTransformer("small") # a smaller pretrained model which is faster to run
custom_transformer = FrameSemanticTransformer("/path/to/model") # load a custom t5 model
By default, models are lazily loaded when detect_frames()
is first called. If you want to load the model sooner, you can call setup()
on a FrameSemanticTransformer
instance to load models immediately.
frame_transformer = FrameSemanticTransformer()
frame_transformer.setup() # load models immediately
Any contributions to improve this project are welcome! Please open an issue or pull request in this repo with any bugfixes / changes / improvements you have!
This project uses Black for code formatting, Flake8 for linting, and Pytest for tests. Make sure any changes you submit pass these code checks in your PR. If you have trouble getting these to run feel free to open a pull-request regardless and we can discuss further in the PR.
The code contained in this repo is released under a MIT license, however the pretrained models are released under an Apache 2.0 license in accordance with FrameNet training data and HuggingFace's T5 base models.
If you use Frame semantic transformer in your work, please cite the following:
@article{chanin2023opensource,
title={Open-source Frame Semantic Parsing},
author={Chanin, David},
journal={arXiv preprint arXiv:2303.12788},
year={2023}
}