This repository contains code and links to datasets for Compositional Generalization research at the Aalto Artificial Intelligence and Deep Learning Research Group (Aalto AI).
This work demonstrates a model that promotes sparse interactions between words and disentangled factors and lead to better compositional generalization performance at a low number of samples on a simple goal-reaching task.
If you wish to refer to this work, please cite it as follows:
@inproceedings{spilsbury-ilin-2022-compositional,
title = "Compositional Generalization in Grounded Language Learning via Induced Model Sparsity",
author = "Spilsbury, Sam and
Ilin, Alexander",
booktitle = "Proceedings of the 2022 Conference of the North American Chapter of the Association for Computational Linguistics: Human Language Technologies: Student Research Workshop",
month = jul,
year = "2022",
address = "Hybrid: Seattle, Washington + Online",
publisher = "Association for Computational Linguistics",
url = "https://aclanthology.org/2022.naacl-srw.19",
pages = "143--155",
}
The main dependencies can be found in the requirements.txt file and can be installed with pip. You will
also need to install babyai from this commit.
The dataset we use for the paper in HDF5 can be found here.
The data is procedurally generated using the process described in Appendix B. We collect 10,000 demonstrations of each trajectory, then split them into in-distribution and out-of-distribution goals.
To generate examples with the bot over many threads, use:
python scripts/generation/babyai/generate_examples_bot.py --help
usage: generate_examples_bot.py [-h]
[--n-trajectories-per-goal N_TRAJECTORIES_PER_GOAL]
[--min-trajectory-length MIN_TRAJECTORY_LENGTH]
[--seeds-and-solutions-buffer SEEDS_AND_SOLUTIONS_BUFFER]
[--env ENV] [--n-goals N_GOALS]
[--n-procs N_PROCS]
output
positional arguments:
output Where to store the resulting bot trajectories
optional arguments:
-h, --help show this help message and exit
--n-trajectories-per-goal N_TRAJECTORIES_PER_GOAL
--min-trajectory-length MIN_TRAJECTORY_LENGTH
--seeds-and-solutions-buffer SEEDS_AND_SOLUTIONS_BUFFER
--env ENV Name of environment to use
--n-goals N_GOALS Number of unique goals in this environment
--n-procs N_PROCS
For example, our invocation looks something like:
python scripts/generation/babyai/generate_examples_bot.py bot_trajectories_10000_each_BabyAI-GoToLocal-v0.pt --n-trajectories-per-goal 10000 --min-trajectory-length 7 --seeds-and-solutions-buffer seends_and_solutions_10000_each_BabyAI-GoToLocal-v0.pt --env BabyAI-GoToLocal-v0 --n-goals 36 --n-procs 8
This will generate the seeds, solve each trajectory and then replay the solutions to get the observations. Note that this process can use quite a bit of memory, since it writes everything to a pickle file at the end.
Once the bot trajectories are generated you'll want to split them into training and OOD validation sets, then pad them so that they can be used with pytorch. This pads them so that each trajectory is the length of the longest trajectory. Do the padding with:
python scripts/generation/babyai/preprocess_data_bot.py --help
usage: preprocess_data_bot.py [-h] --bot-trajectories BOT_TRAJECTORIES output
positional arguments:
output
optional arguments:
-h, --help show this help message and exit
--bot-trajectories BOT_TRAJECTORIES
If you want to convert the pickle into something a little more portable, you can use the scripts/generation/babyai/dataset_to_portable.py script. This
converts the pickle file into an hdf5 file.
python scripts/generation/babyai/dataset_to_portable.py --help
usage: dataset_to_portable.py [-h] pickle_file hdf5_file
positional arguments:
pickle_file
hdf5_file
optional arguments:
-h, --help show this help message and exit
The key contributions of the work (and their corresponding locations):
- A form of factored attention (operating over factored representations) plus sparsity penalty (Section 4.1)
- Factored embedding
models/interaction/independent_attention:IndependentAttentionModel:forward. This uses the providedattrib_offsetsto index into a single embedding, partitioned by the offsets into embeddings for each factor. Note that there is a separate channel for each of the factor embeddings - they are not concatenated together. - Factored attention
models/interaction/independent_attention:IndependentAttentionModel:forward. Attention between the words and each cell in the observation state is computed over every factor separately, then multiplied together (using exp-sum-log). See equation (1) in the paper. - Sparsity penalty between outer product of word embedding space and attribute embedding space
models/discriminator/independent_attention:IndependentAttentionProjectionHarness:training_step. This is computed as logged asl1cand added to the loss from the original harness training step.
- Factored embedding
- Discriminator training method to learn to find goals in unlabelled observations (Section 4.2).
- The "Masking Module" is found in
models/img_mask:ImageComponentsToMask - The training step for the discriminator is found in
models/discriminator/harness:ImageDiscriminatorHarness. Here both $\mathcal{L}{\text{img}}$ and $\mathcal{L}{\text{int}}$ are computed. - The sampling and dataloading procedure are found in
datasets/discriminator:DiscriminatorDataset. Here the sampling procedure described in Appendix D is implemented.
- The "Masking Module" is found in
- Planning Module
- MVProp network
models/vin/mvprop:MVProp2D - Q-value convolutional net
models/vin/resnet_value:BigConvolutionValueMapExtractor - Conservative Q Learning-like penalty
models/vin/harness:VINHarness.training_step
- MVProp network
The baselines used in the paper for the sample efficiency
test can be found in models/imitation
| Name | Module | Description |
|---|---|---|
| FiLM/GRU | baseline |
Encode the instruction with LSTM and FiLM-modulate convolutional processing of observations, with global spatial max pooling |
| Transformer | transformer |
Encode the instruction using a position-encoded transformer encoder, decode the image using cross-attention between encoded instruction and 2D-position image, predicting the policy from a final CLS token |
In the paper the following ablation of the model is reported:
| Name | Experiment Name | Description |
|---|---|---|
| MVProp/CNN | vin_sample_nogoal_16_logsumexp_k_0:mvprop |
Do not perform any value iteration steps, instead immediately concatenate the result of the interaction network to the observation and regress Q-values from there |
Other ablations not reported in the paper but available in the code:
| Name | Experiment Name | Description |
|---|---|---|
| MVProp/Transformer | vin_sample_nogoal_16_logsumexp_ignorance_transformer:mvprop |
Use pre-trained Transformers (from the discriminator) to detect goals as opposed to the sparse factored attention |
There are three different things to train in order to reproduce the results in the paper.
For all three training script, logging happens to tensorboard files in the
directory given by --experiment / --model. You can run tensorboard
in that directory to see the results as the training is running. We also use
the tensorboard log files later on for analysis.
python scripts/train/train_imitation.py --help
usage: train_imitation.py [-h] --data DATA --exp-name EXP_NAME --seed SEED
[--model {film_lstm_policy,conv_transformer,sentence_encoder_image_decoder,fused_inputs_next_step_encoder,fused_inputs_autoregressive_transformer}]
[--limit LIMIT] [--vlimit VLIMIT] [--tlimit TLIMIT]
[--total TOTAL] [--iterations ITERATIONS]
[--n-eval-procs N_EVAL_PROCS]
[--batch-size BATCH_SIZE]
[--check-val-every CHECK_VAL_EVERY]
optional arguments:
-h, --help show this help message and exit
--data DATA
--exp-name EXP_NAME
--seed SEED
--model {film_lstm_policy,conv_transformer,sentence_encoder_image_decoder,fused_inputs_next_step_encoder,fused_inputs_autoregressive_transformer}
--limit LIMIT
--vlimit VLIMIT
--tlimit TLIMIT
--total TOTAL Total number of instances per task
--iterations ITERATIONS
--n-eval-procs N_EVAL_PROCS
Number of processes to run evaluation with
--batch-size BATCH_SIZE
Batch size for training
--check-val-every CHECK_VAL_EVERY
Check val every N steps
The main thing that changes here is --model. The available models are:
| Name | Module | Description |
|---|---|---|
| FiLM/GRU | film_lstm_policy |
LSTM/FiLM |
| Transformer | sentence_encoder_image_decoder |
Transformer Encoder-Decoder (sometimes referred to as pure_transformer) |
| Next-step Encoder Transformer | fused_inputs_next_step_encoder |
Transformer Encoder-only model (not used in the paper) |
| Autoregressive Encoder Transformer | fused_inputs_next_step_encoder |
Transformer Encoder-only model which predicts all future steps from single frame (not used in the paper) |
For the paper we used the following invocation:
python scripts/train/train_imitation.py --exp-name imitation --model $MODEL --limit $LIMIT --vlimit 20 --tlimit 40 --iterations 120000 --data $DATA_PATH --seed $SEED
python scripts/train/train_discriminator.py --help
usage: train_discriminator.py [-h] --data DATA --exp-name EXP_NAME --seed SEED
[--model {film,transformer,independent,independent_noreg,simple,simple_noreg}]
[--limit LIMIT] [--vlimit VLIMIT]
[--tlimit TLIMIT] [--iterations ITERATIONS]
[--total TOTAL] [--batch-size BATCH_SIZE]
[--check-val-every CHECK_VAL_EVERY]
optional arguments:
-h, --help show this help message and exit
--data DATA
--exp-name EXP_NAME
--seed SEED
--model {film,transformer,independent,independent_noreg,simple,simple_noreg}
--limit LIMIT Training set limit (per task)
--vlimit VLIMIT Validation set limit (per task)
--tlimit TLIMIT Test set limit (per task)
--iterations ITERATIONS
--total TOTAL Total number of instances per task
--batch-size BATCH_SIZE
Batch size for training
--check-val-every CHECK_VAL_EVERY
Check val every N steps
The main thing that changes here is --model. The available models are:
| Name | Module | Description |
|---|---|---|
| FiLM/GRU | film |
LSTM/FiLM |
| Transformer | transformer |
Transformer Encoder-Decoder |
| Sparse Factored Attention | independent |
Our "Factored Attention" model with sparsity |
| Factored Attention | independent_noreg |
Our "Factored Attention" model without sparsity |
| Sparse Attention | simple |
Non-factored attention where the input factor embeddings are concatenated together and projected into the word embedding space, with sparsity |
For the paper we used the following invocation:
python scripts/train/train_discriminator.py --exp-name discriminator_sample_nogoal_16_logsumexp --model $MODEL --limit $LIMIT --vlimit 20 --tlimit 40 --iterations $ITERATIONS --data $DATA_PATH --seed $SEED --batch-size 1024
python scripts/train/train_vin.py --help
usage: train_vin.py [-h] --data DATA --exp-name EXP_NAME --seed SEED
[--model {mvprop}] [--limit LIMIT] [--vlimit VLIMIT]
[--tlimit TLIMIT] [--total TOTAL]
[--iterations ITERATIONS] [--n-eval-procs N_EVAL_PROCS]
[--batch-size BATCH_SIZE]
[--check-val-every CHECK_VAL_EVERY]
[--interaction-model {independent,transformer}]
[--load-interaction-model LOAD_INTERACTION_MODEL]
[--vin-k VIN_K] [--device DEVICE] [--show-progress]
optional arguments:
-h, --help show this help message and exit
--data DATA
--exp-name EXP_NAME
--seed SEED
--model {mvprop}
--limit LIMIT
--vlimit VLIMIT
--tlimit TLIMIT
--total TOTAL Total number of instances per task
--iterations ITERATIONS
--n-eval-procs N_EVAL_PROCS
Number of processes to run evaluation with
--batch-size BATCH_SIZE
Batch size for training
--check-val-every CHECK_VAL_EVERY
Check val every N steps
--interaction-model {independent,transformer}
Which interaction module to use
--load-interaction-model LOAD_INTERACTION_MODEL
Path to an interaction model to load
--vin-k VIN_K Number of VIN iterations
--device DEVICE Which device to use
--show-progress Show the progress bar
The main thing that changes here is --interaction-model. The available models are:
| Name | Module | Description |
|---|---|---|
| Transformer | transformer |
Transformer Encoder-Decoder |
| Sparse Factored Attention | independent |
Our "Factored Attention" model with sparsity |
The appropriate value of --vin-k depends on the size of the observation space. You should set
it so that it is possible for a value from one end of the observation to propgate to the other end
if necessary, so that state-values can be correctly estimated. Since the kernel size for value propagation
is 3, you can use
When training this model, you can load a pre-trained interaction model used for goal-detection with
--load-interaction-model and specifying a path to the saved weights.
For the paper we used the following invocation:
BASE_MODEL=$DISCRIMINATOR_MODELS_PATH/discriminator_sample_nogoal_16_logsumexp/${INTERACTION_MODEL_NAME}/discriminator_sample_nogoal_16_logsumexp_s_${SEED}_m_${INTERACTION_MODEL_NAME}_it_200000_b_1024_l_${LIMIT}.pt
python scripts/train_vin.py --exp-name vin_sample_nogoal_16_logsumexp_ignorance_${INTERACTION_MODEL_NAME} --model $MODEL --limit $LIMIT --vlimit 20 --tlimit 40 --iterations $ITERATIONS --data $DATA_PATH --seed $SEED --interaction-model ${INTERACTION_MODEL_NAME} --load-interaction-model $BASE_MODEL
Once the experimental runs are in, you should postprocess the checkpoints to prune out optimizer information.
Use the convert_checkpoints.py script for that.
python scripts/postprocessing/convert_checkpoints.py --help
usage: convert_checkpoints.py [-h] [--dry-run] [--pattern PATTERN] directory
positional arguments:
directory
optional arguments:
-h, --help show this help message and exit
--dry-run
--pattern PATTERN
This converts all the checkpoints in a directory (recursively) such that the optimizer information is removed.
Model checkpoints and logs we generated by training on our GPU cluster can be found here
Now that you have the checkpoints, its time to do the analysis and reproduce the results in the paper!
These are generated using the rliable package. First we need to extract the sample efficiency information from the logs:
python scripts/analysis/babyai/extract_sample_efficiency_curves.py --help
usage: extract_sample_efficiency_curves.py [-h]
[--limits [LIMITS [LIMITS ...]]]
[--check-experiments [CHECK_EXPERIMENTS [CHECK_EXPERIMENTS ...]]]
[--check-models]
[--n-procs N_PROCS]
logs_dir models_dir output_file
positional arguments:
logs_dir
models_dir
output_file
optional arguments:
-h, --help show this help message and exit
--limits [LIMITS [LIMITS ...]]
--check-experiments [CHECK_EXPERIMENTS [CHECK_EXPERIMENTS ...]]
Experiments in the format
experiment:model:iterations:cut_at
--check-models Whether to check if the models exist
--n-procs N_PROCS
You can do this over multiple processes in order to speed it up a bit. The script only needs the logs directory and models directory. An example invocation might be:
python scripts/analysis/babyai/extract_sample_efficiency_curves.py $LOGS_PATH $MODELS_PATH sample_efficiency_curves.json
Then to plot the curves (what you see in the figure) you can use
python scripts/analysis/babyai/plot_sample_efficiency_curves.py sample_efficiency_curves.json id.pdf ood.pdf
This creates two files containing the in-distribution and out-of-distribution curves, respectively.
First we need to extract the predictions:
python scripts/analysis/babyai/extract_sample_predictions.py --help
usage: extract_sample_predictions.py [-h] [--models [MODELS [MODELS ...]]]
[--limits [LIMITS [LIMITS ...]]]
[--experiment EXPERIMENT]
[--train-index TRAIN_INDEX]
[--valid-index VALID_INDEX]
dataset logs_dir models_dir output_json
positional arguments:
dataset
logs_dir
models_dir
output_json
optional arguments:
-h, --help show this help message and exit
--models [MODELS [MODELS ...]]
--limits [LIMITS [LIMITS ...]]
--experiment EXPERIMENT
--train-index TRAIN_INDEX
--valid-index VALID_INDEX
The main arugments to pay attention to here are --train-index and --valid-index as they specify
which sample in the dataset should be used for the visualization.
An example invocation might be:
python scripts/analysis/babyai/extract_sample_predictions.py $DATASET_PATH $LOGS_PATH $MODELS_PATH sample_predictions.json --train-index 0 --valid-index 3
Once that's done you can plot the predictions.
python scripts/analysis/babyai/plot_sample_predictions.py sample_predictions.json sample_predictions.pdf
First we need to extract the embedding dot products
python scripts/analysis/babyai/extract_embedding_dot_products.py --help
usage: extract_embedding_dot_products.py [-h] [--experiment EXPERIMENT]
[--models [MODELS [MODELS ...]]]
[--limits [LIMITS [LIMITS ...]]]
logs_dir models_dir output_json
positional arguments:
logs_dir
models_dir
output_json
optional arguments:
-h, --help show this help message and exit
--experiment EXPERIMENT
--models [MODELS [MODELS ...]]
--limits [LIMITS [LIMITS ...]]
An example invocation might be:
python scripts/analysis/babyai/extract_embedding_dot_products.py $LOGS_PATH $MODELS_PATH internal_correlations.json
Once that's done you can plot them:
python scripts/analysis/babyai/plot_embedding_dot_products.py internal_correlations.json internal_correlations.pdf