This is the codebase associated with the following paper:

Data Distributional Properties Drive Emergent In-Context Learning in Transformers (arXiv)
Stephanie C.Y. Chan, Adam Santoro, Andrew K. Lampinen, Jane X. Wang, Aaditya Singh, Pierre H. Richemond, Jay McClelland, Felix Hill

The experiments involve training and evaluating a transformer on sequences of Omniglot image-label pairs, to elicit and measure (few-shot) in-context learning vs in-weights learning. See Sec 2 of the paper for an overview of the experimental design.

To install the necessary requirements:

python3 -m venv eicl_venv
source eicl_venv/bin/activate
pip install --upgrade pip
pip install -r ./emergent_in_context_learning/requirements.txt

Default experiment configurations are provided in configs/, and can be used in $PATH_TO_CONFIG in the launch commands below.

• images_all_exemplars.py: Each character class consists of 20 image examples (the original Omniglot problem).
• images_augmented.py: We augment the total number of classes to 8x the original number, by applying transformations to each image class: flip left or right + rotate 0, 90, 180, or 270 degrees.
• images_identical.py: Each character class consists only of a single image (the 1st of the 20 examples provided in the original Omniglot dataset)
• symbolic.py: (relatively untested; not used in the paper)

Config files can be edited or forked as desired.

Omniglot sequences are generated in datasets/data_generators.py.

The image classes are divided into training and holdout. Training classes can be "common" or "rare". The training classes can be uniformly or Zipf-distributed (jointly over both common and rare classes). Related configurations are set in config.data.generator_config.

There are few different types of data sequences:

• bursty : These are the canonical bursty (and non-bursty) sequences used in training in the paper
• no_support_common, no_support_rare, non_support_zipfian : These sequences enforce that the query class does not appear anywhere in the context, and are the sequences used for evaluating in-weights learning in the paper. They can consist entirely of common classes, rare classes, or be Zipf-distributed over all training classes.
• fewshot_common, fewshot_rare, fewshot_zipfian, fewshot_holdout : These sequence are standard k-shot n-way fewshot sequences, and are used for evaluating in-context learning in the paper. They can exist of holdout classes, common classes, rare classes, or be Zipf-distributed over all training classes.
• mixed: A mix of standard fewshot and iid randomly generated sequences.

Sequence types are specified in config.data.train_seqs and in config.eval_modes (with an additional eval_ prefix). You may specify a list of eval modes, to evaluate the same learner on multiple sequence types.

See experiment/experiment.py: _get_ds_seqs and datasets/data_generators.py: SeqGenerator for more details on settings, which are specified in config.data.seq_config.

These commands should be executed from the directory that you cloned the repository into.

To run training:

$ python -m emergent_in_context_learning.experiment.experiment --config $PATH_TO_CONFIG --jaxline_mode train --logtostderr
# (save checkpoints using Ctrl+C)

To evaluate a trained model, override config.restore_path with the subdirectory of config.checkpoint_dir containing the relevant checkpoint ($CKPT_DIR below).

To evaluate on in-context learning (on holdout classes):

$ python -m emergent_in_context_learning.experiment.experiment --config $PATH_TO_CONFIG --logtostderr --config.one_off_evaluate --config.restore_path $CKPT_DIR --jaxline_mode eval_fewshot_holdout

To evaluate on in-weights learning (on trained classes):

$ python -m emergent_in_context_learning.experiment.experiment --config $PATH_TO_CONFIG --logtostderr --config.one_off_evaluate --config.restore_path $CKPT_DIR --jaxline_mode eval_no_support_zipfian

If you use this work, please cite the following paper

@misc{chan_data_2022,
  title = {Data Distributional Properties Drive Emergent In-Context Learning in Transformers},
  author = {Chan, Stephanie C. Y. and Santoro, Adam and Lampinen, Andrew K. and Wang, Jane X. and Singh, Aaditya and Richemond, Pierre H. and McClelland, Jay and Hill, Felix},
  journal = {Neural Information Processing Systems},
  year = {2022},
}

We would also like to thank the following colleagues for their contributions to the implementation of the transformer model: Igor Babuschkin, Junyoung Chung, David Choi, Tamara Norman, Sebastian Borgeaud, Jack Rae, David Saxton, Yujia Li, Phil Blunsom, Maribeth Rauh, Roman Ring, Nate Kushman, Vinicius Zambaldi, Tom Hennigan

Copyright 2022 DeepMind Technologies Limited

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