A Library for active learning. Supports text classification and sequence tagging tasks.
Project description
рџ› ALToolbox
ALToolbox is a framework for practical active learning in NLP.
Installation | Quick Start | Overview | Docs | Citation
ALToolbox is a framework for active learning annotation in natural language processing. Currently, the framework supports text classification and sequence tagging tasks. ALToolbox provides state-of-the-art query strategies, serverless annotation tool for Jupyter IDE, and a set of tools that help to reduce computational overhead / duration of AL iterations and increase annotated data reusability.
вљ™пёЏ Installation
pip install acleto
To annotate instances for active learning in Jupyter Notebook or Jupyter Lab one have to install additional widget after framework installation. In case of Jupyter Notebook usage run:
jupyter nbextension install --py --symlink --sys-prefix text_selector
jupyter nbextension enable --py --sys-prefix text_selector
In case of Jupyter Lab usage run:
jupyter labextension install js
jupyter labextension install text_selector
рџ’« Quick Start
For quick start, please see the examples of launching an active learning annotation or benchmarking a novel query stategy / unlabeled pool subsampling strategy for sequence tagging and text classification tasks:
# | Notebook |
---|---|
1 | Launching Active Learning for Token Classification |
2 | Launching Active Learning for Text Classification |
3 | Benchmarking a novel AL query strategy / unlabeled pool subsampling strategy |
рџ” Overview
1. Query Strategies
3. Unlabeled Pool Subsampling Strategies
# | Strategy | Citation |
---|---|---|
1 | UPS | Citation |
2 | NaГЇve | Citation |
3 | Random | - |
4. Pipelines for postprocessing of annotated data and preparation of acquisition models
- PLASM postprocessing pipeline for annotated data reusability.
- Acquisition model distillation.
- Domain adaptation of acquisition models.
5. GUI Annotator tool in Jupyter IDE
Our framework provides a serverless GUI annotation tool integrated into the Jupyter IDE:
6. Extensible benchmark for query strategies
TODO:
рџ“• Documentation
Usage
The configs
folder contains config files with general settings. The experiments
folder contains config files with experimental design. To run an experiment with a chosen configuration, specify config file name in HYDRA_CONFIG_NAME
variable and run train.sh
script (see ./examples/al
for details).
For example to launch PLASM on AG-News with ELECTRA as a successor model:
cd PATH_TO_THIS_REPO
HYDRA_CONFIG_PATH=../experiments/ag_news HYDRA_EXP_CONFIG_NAME=ag_plasm python active_learning/run_tasks_on_multiple_gpus.py
Config structure explanation
cuda_devices
: list of CUDA devices to use: one experiment on one CUDA device.cuda_devices=[0,1]
means using zero-th and first devices.config_name
: name of config from configs folder with general settings: dataset, experiment setting (e.g. LC/ASM/PLASM), model checkpoints, hyperparameters etc.config_path
: path to config with general settings.command
: .py file to run. For AL experiments, use run_active_learning.py.args
: arguments to modify from a general config in the current experiment.acquisition_model.name=xlnet-base-cased
means that xlnet-base-cased will be used as an acquisition model.seeds
: random seeds to use.seeds=[4837, 23419]
means that two separate experiments with the same settings (except for seed) will be run: one with seed == 4837, one with seed == 23419.
Output Explanation
By default, the results will be present in the folder RUN_DIRECTORY/workdir_run_active_learning/DATE_OF_RUN/${TIME_OF_RUN}_${SEED}_${MODEL_CHECKPOINT}
. For instance, when launching from the repository folder: al_nlp_feasible/workdir/run_active_learning/2022-06-11/15-59-31_23419_distilbert_base_uncased_bert_base_uncased
.
- When running a classic AL experiment (acquisition and successor models coincide, regardless of using UPS), the file with the model metrics is
acquisition_metrics.json
. - When running an acquisition-successor mismatch experiment, the file with the model metrics is
successor_metrics.json
. - When running a PLASM experiment, the file with the model metrics is
target_tracin_quantile_-1.0_metrics.json
(-1.0 stands for the filtering value, meaning adaptive filtering rate; when using a deterministic filtering rate (e.g. 0.1), the file will be namedtarget_tracin_quantile_0.1_metrics.json
). The file with the metrics of the model without filtering istarget_metrics.json
.
Post-processing
Our framework provides tools for effective data post-processing for its re-usability and a possibility to build powerful models on it.
PLASM, which aims to alleviate the acquisition-successor mismatch problem and allow to build a model of an
arbitrary type using the labeled data without performance degradation, is implemented in post_processing/pipeline_plasm
.
It uses the config cls_plasm
/ ner_plasm
(from `jupyterlab_demo/configs). A brief explanation of the config structure:
- pseudo-labeling model parameters are contained in the key
labeling_model
; - successor model parameters are contained in the key
successor_model
; - post-processing options are contained in the key
post_processing
:label_smoothing
: str / float / None, a parameter for label smoothing (LS) for pseudo-labeled instances. Accepts several options:- "adaptive": LS value equals the quality of the labeling model on the validation data.
- float, 0 < value < 1: absolute value of label smoothing
- None (default): no label smoothing is used
labeled_weight
: int / float, weight for the labeled-by-human data. 1 < value < +infuse_subsample_for_pl
: int / float / None, the size of the subsample used for pseudo-labeling (float means taking the share of the unlabeled data). None means that no subsampling is used.uncertainty_threshold
: float / None, the value of the threshold for filtering by uncertainty. If None, no filtering by uncertainty is used.filter_by_quantile
: bool, only used for classification, ignored ifuncertainty_threshold
is None. If True,uncertainty_threshold
most uncertain instances are filtered. Otherwise, all instances whose (1 - max_prob) <uncertainty_threshold
are filtered.tracin
:use
: bool, whether to use TracIn for filteringmax_num_processes
: int, value > 0, maximum number of processes per one GPUquantile
: str / float (0 < value < 1), share of unlabeled data instances to filter using the TracIn score.num_model_checkpoints
: int, value > 0, how many model checkpoints to save and use for TracIn.nu
: float / int, value for TracIn algorithm.
🆕️ New strategies addition
An AL query strategy should be designed as a function that:
- Receives 3 positional arguments and additional strategy kwargs:
-
model
of inherited classTransformersBaseWrapper
orPytorchEncoderWrapper
orFlairModelWrapper
: model wrapper; -X_pool
of classDataset
orTransformersDataset
: dataset with the unlabeled instances; -n_instances
of classint
: number of instances to query; -kwargs
: additional strategy-specific arguments. - Outputs 3 objects in the following order:
query_idx
of classarray-like
: array with the indices of the queried instances;query
of classDataset
orTransformersDataset
: dataset with the queried instances;uncertainty_estimates
of classnp.ndarray
: uncertainty estimates of the instances fromX_pool
. The higher the value - the more uncertain the model is in the instance.
The function with the strategy should be named the same as the file where it is placed (e.g. function def my_strategy
inside a file path_to_strategy/my_strategy.py
).
Use your strategy, setting al.strategy=PATH_TO_FILE_YOUR_STRATEGY
in the experiment config.
The example is presented in examples/benchmark_custom_strategy.ipynb
🆕️ New pool subsampling strategies addition
The addition of a new pool subsampling query strategy is similar to the addition of an AL query strategy. A subsampling strategy should be designed as a function that:
- It must receive 2 positional arguments and additional subsampling strategy kwargs:
-
uncertainty_estimates
of classnp.ndarray
: uncertainty estimates of the instances in the order they are stored in the unlabeled data; -gamma_or_k_confident_to_save
of classfloat
orint
: either a share / number of instances to save (as in random / naive subsampling) or an internal parameter (as in UPS); -kwargs
: additional subsampling strategy specific arguments. - It must output the indices of the instances to use (sampled indices) of class
np.ndarray
.
The function with the strategy should be named the same as the file where it is placed (e.g. function def my_subsampling_strategy
inside a file path_to_strategy/my_subsampling_strategy.py
).
Use your subsampling strategy, setting al.sampling_type=PATH_TO_FILE_YOUR_SUBSAMPLING_STRATEGY
in the experiment config.
The example is presented in examples/benchmark_custom_strategy.ipynb
Datasets
The research has employed 2 Token Classification datasets (CoNLL-2003, OntoNotes-2012) and 2 Text Classification datasets (AG-News, IMDB). If one wants to launch an experiment on a custom dataset, they need to use one of the following ways to add it:
- Upload to Hugging Face datasets and set:
config.data.path=datasets, config.data.dataset_name=DATASET_NAME, config.data.text_name=COLUMN_WITH_TEXT_OR_TOKENS_NAME, config.data.label_name=COLUMN_WITH_LABELS_OR_NER_TAGS_NAME
- Upload to data/DATASET_NAME folder, create train.csv / train.json file with the dataset, and set:
config.data.path=PATH_TO_THIS_REPO/data, config.data.dataset_name=DATASET_NAME, config.data.text_name=COLUMN_WITH_TEXT_OR_TOKENS_NAME, config.data.label_name=COLUMN_WITH_LABELS_OR_NER_TAGS_NAME
- * Upload to data/DATASET_NAME train.txt, dev.txt, and test.txt files and set the arguments as in the previous point.
- ** Upload to data/DATASET_NAME with each folder for each class, where each file in the folder contains a text with the label of the folder. For details, please see the bbc_news dataset in ./data. The arguments must be set as in the previous two points.
* - only for Token Classification datasets
** - only for Text Classification datasets
Models
The current version of the repository supports all models from HuggingFace Transformers, which can be used with AutoModelForSequenceClassification
/ AutoModelForTokenClassification
classes (for Text / Token classification). For CNN-based / BiLSTM-CRF models, please see the al_cls_cnn.yaml / al_ner_bilstm_crf_flair.yaml configs from ./configs folder for details.
Testing
By default, the tests will be run on the cuda:0
device if CUDA is available or on CPU, otherwise. If one wants to manually specify the device for running the tests:
- On CPU:
CUDA_VISIBLE_DEVICES="" python -m pytest PATH_TO_REPO/tests
; - On CUDA:
CUDA_VISIBLE_DEVICES="DEVICE_OR_DEVICES_NUMBER" python -m pytest PATH_TO_REPO/tests
.
We recommend to use CPU for the robustness of the results. The tests for CUDA are written under Tesla V100-SXM3 32GB, CUDA V.10.1.243.
рџ‘Ї Alternatives
FAMIE, Small-Text, modAL, ALiPy, libact
рџ’¬ Citation
рџ“„ License
В© 2022 Autonomous Non-Profit Organization "Artificial Intelligence Research Institute" (AIRI). All rights reserved.
Licensed under the MIT License.
Project details
Download files
Download the file for your platform. If you're not sure which to choose, learn more about installing packages.
Source Distribution
File details
Details for the file acleto-0.0.7.tar.gz
.
File metadata
- Download URL: acleto-0.0.7.tar.gz
- Upload date:
- Size: 173.2 kB
- Tags: Source
- Uploaded using Trusted Publishing? No
- Uploaded via: twine/4.0.1 CPython/3.9.11
File hashes
Algorithm | Hash digest | |
---|---|---|
SHA256 | 861a3b07d0713b1b3efd0d1e5cbf20708178638d916d796642a004f938272bea |
|
MD5 | fcd9feedfc4c02e40e1a1361e0d569ce |
|
BLAKE2b-256 | 9bc95401f0cfbed427e11dfc603205cf09a82cfc1bedbee96ed38d0f22396a9a |