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PyTorch implementation of "Transparency by Design: Closing the Gap Between Performance and Interpretability in Visual Reasoning"

Home Page: https://arxiv.org/abs/1803.05268

License: MIT License

Jupyter Notebook 94.58% Python 5.42%

machine-learning pytorch visualization deep-learning visual-question-answering vqa neural-networks

tbd-nets's Introduction

Transparency-by-Design networks (TbD-nets)

This repository contains code for replicating the experiments and visualizations from the paper

Transparency by Design: Closing the Gap Between Performance and Interpretability in Visual Reasoning

David Mascharka, Philip Tran, Ryan Soklaski, Arjun Majumdar

The paper describes Transparency-by-Design networks (TbD-nets), which are built around a visual attention mechanism. This repository contains the model architecture put forward in the paper and code that will allow you to

Produce the visualizations from the paper
Ask a natural-language question about an image you provide
Train a model from scratch on the CLEVR dataset
Predict answers on the CLEVR test set

A visualization of the output produced by our TbD-net model can be seen below.

If you find this code useful in your research, please cite

@InProceedings{Mascharka_2018_CVPR,
author = {Mascharka, David and Tran, Philip and Soklaski, Ryan and Majumdar, Arjun},
title = {Transparency by Design: Closing the Gap Between Performance and Interpretability in Visual Reasoning},
booktitle = {The IEEE Conference on Computer Vision and Pattern Recognition (CVPR)},
month = {June},
year = {2018}
}

Full VQA

To ask a natural-language question and provide an image to the model and get an answer and reasoning chain back, see the full VQA example notebook. This will define all the machinery you need to perform the full VQA task and will allow you to download the necessary models. Try it with Binder!

Recreating Our Visualizations

You can use Binder to use our model without any setup!

To reproduce our work on your local machine, you'll need to clone this repository and set up PyTorch. We also recommend using CUDA and cuDNN if you have a GPU available.

You can then open up the visualize-output notebook. That will walk you through running our model and generates all the figures we use in our paper. It will also download one of our pretrained models. From there, you can play around with the images we provide without having to download any outside data or models. If you would like to experiment with our other models, see the downloading models section.

Training a Model

To train a model from scratch, there are a few requirements to take care of. We assume you have already set up PyTorch and CUDA/cuDNN if you plan on using a GPU (which is highly recommended).

1. Getting data

The CLEVR dataset is available at its project page. The first step for training is to download that data.

You will also need to extract features and process the question files to produce programs before training a model. The instructions here provide a method for this. We recommend cloning that repository and following those instructions.

NOTE: to extract 28x28 features, you will need to add the --model_stage 2 option to the extract_features.py command. Following the conventions on that page, the command you want is:

python scripts/extract_features.py \
    --input_image_dir data/CLEVR_v1.0/images/train \
    --output_h5_file data/train_features.h5 \
    --model_stage 2

If you want to train on the 14x14 feature maps, you can follow Justin's instructions exactly.

After you have finished the above, you will have several HDF5 files containing the image features and questions, and a vocabulary file. While we do provide a DataLoader that will work with the HDF5 files, we personally find NumPy npy files more robust and generally more pleasant to work with, so we default to using those.

a. Converting HDF5 to npy

Note that this step is completely optional. The h5_to_np script will produce npy files from your HDF5 files.

Note that the largest NumPy data file (train_features.npy) is 53 gigabytes for the 14x14 feature maps or 105 gigabytes for the 28x28 feature maps, meaning you will need a substantial amount of RAM available on your machine to create these files. If you do not have enough memory available, use the HDF5 data loader instead of trying to convert these files.

To convert your HDF5 files to npy files, invoke one of the following, depending on whether you want to convert images to NumPy format as well:

python h5_to_np -q /path/to/questions.h5 -f /path/to/features.h5 -i /path/to/images.h5 -d /path/to/dest/
python h5_to_np -q /path/to/questions.h5 -f /path/to/features.h5 -d /path/to/destination/

2. Training the model

The train-model notebook will then walk through the training process. Our recommended directory structure (which is shown in the notebook) is to create a symlink to your data files inside the data folder. This can be done via:

ln -s /path/to/the/data/train_questions.npy data/training/
ln -s /path/to/the/data/train_image_idxs.npy data/training/
# etc

for data in npy format, or via:

ln -s /path/to/the/data/train_features.h5 data/training/
ln -s /path/to/the/data/train_questions.h5 data/training/
# likewise for validation

for data in HDF5 format.

If you prefer a different directory structure, update the data loader paths in the notebook. The notebook will walk through training a model from this point.

Testing a Model

Note that the testing data does not provide ground truth programs, so we will need to generate programs from the questions for testing. We do not focus on this component of the network in our work, so we reuse the program generator from Johnson et al. We have repackaged the sequence-to-sequence model they use for this, removing unnecessary functionality and updating the code to run on PyTorch versions later than 0.1. We provide a model checkpoint that we trained ourselves, so you don't need to download and use their model. The test-eval notebook will walk through the process to produce a file containing the predicted test answers.

Notes

Downloading Models

To download models, you can use the download_pretrained_models.py script, or download them programmatically as we do in the visualize output and full VQA notebooks.

There are several pretrained models available. If you would like to play with a specific model from the table of results in the paper, you certainly can. However, we only provide extracted features for the model trained on 28x28 feature maps, so if you want to use the 14x14 feature maps you'll need to extract those features yourself. See the getting data section for details on that. The download options for the script are:

python utils/download_pretrained_models.py -m original
python utils/download_pretrained_models.py -m reg
python utils/download_pretrained_models.py -m hres
python utils/download_pretrained_models.py -m all

The default is hres which downloads only the models trained with higher-resolution 28x28 feature maps and the regularization factor (see paper text for details). This results in cleaner looking attention masks, state-of-the-art performance, and is recommended. If you want to replicate the other results in the table, original will give only the models trained without regularization on 14x14 feature maps, reg will download the models trained with regularization on 14x14 feature maps, and all will download everything.

Python

We only recommend running the code with Python 3, having done all our development using Python 3.6. While the code may be coerced into running in Python 2, we will not support Python 2, so please do not open issues that are related to Python 2 support.

PyTorch

Our development was done using PyTorch v0.1.12, v0.2.0, and v0.3.0 and has been tested with v0.4. As such, our code should run even on PyTorch versions earlier than 0.2 without modifications. However, we do recommend running on PyTorch 0.2.0 or later. For setting up PyTorch, see the official installation instructions. The specific hash that the original model from our paper was developed from is here.

To use PyTorch <0.4, clone the repository and check out tags/torch0.3. For PyTorch 0.4 and above, master will run.

CUDA/cuDNN

Our code is tested under CUDA 8 and CUDA 9 with cuDNN 5 and cuDNN 7, respectively. For setting up CUDA, see the NVIDIA documentation. We recommend using cuDNN, which is also available from NVIDIA.

Operating Systems

Our development was done on CentOS 6 and Ubuntu 16.04. The code has also been tested under Arch Linux.

Setting up a conda environment

If you like, you can use the environment.yml configuration to set up a development environment if you use conda. This is the environment that Binder uses to give a live notebook for the visualizations. To create an environment using this, run

conda env create -f environment.yml

The environment can then be activated with source activate tbd-env.

Copyright

DISTRIBUTION STATEMENT A. Approved for public release: distribution unlimited.

This material is based upon work supported by the Assistant Secretary of Defense for Research and Engineering under Air Force Contract No. FA8721-05-C-0002 and/or FA8702-15-D-0001. Any opinions, findings, conclusions or recommendations expressed in this material are those of the author(s) and do not necessarily reflect the views of the Assistant Secretary of Defense for Research and Engineering.

MIT Proprietary, Subject to FAR52.227-11 Patent Rights - Ownership by the contractor (May 2014)

The software/firmware is provided to you on an As-Is basis

Delivered to the U.S. Government with Unlimited Rights, as defined in DFARS Part 252.227-7013 or 7014 (Feb 2014). Notwithstanding any copyright notice, U.S. Government rights in this work are defined by DFARS 252.227-7013 or DFARS 252.227-7014 as detailed above. Use of this work other than as specifically authorized by the U.S. Government may violate any copyrights that exist in this work.

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tbd-nets's Issues

Properties not specified in modules?

Hey, I've read the codes for different modules. It seems that the modules does not contain any design for encoding properties (e.g. red or blue for color property). Take attention module for example, if we're not sure what color we are attending, how can the module attend to the right locations? Please correct me if I missed something, thanks!

Training the model Step 2

About converting HDF5 to npy

Hi, what is the advantage of converting HDF5 to npy first? Will it accelerate the training speed or accuracy?

No longer runs on mybinder.org

Hey,

I was wondering if you tried running this lately and had an ideas as to why it doesn't run successfully anymore on mybinder.org. I don't really know much about the code in the repo nor pytorch. From looking at the environment.yml and the errors I get my guess would be that there is now a newer version of pytorch that changed conventions or some such?

I've used this repository before as an example in talks about Binder and wanted to do so again but during my run through I noticed that it doesn't work anymore. If you don't have time to fix this that is totally fine, I'll find a different repo for demo purposes.

RuntimeError: element 0 of tensors does not require grad and does not have a grad_fn

Trying to reproduce the experiments on train-model.ipynb and using the proposed enviroment with pytorch 0.4.1 the code produced the following error:

RuntimeError                              Traceback (most recent call last)
<ipython-input-14-82ec354902a5> in <module>()
      6     epoch += 1
      7     print('starting epoch', epoch)
----> 8     train_epoch()
      9 
     10 save_checkpoint(epoch, 'example-{:02d}.pt'.format(epoch))

<ipython-input-13-2216c33e0bef> in train_epoch()
     33 
     34         loss_file.write('Loss: {}\n'.format(loss.item()))
---> 35         loss.backward()
     36         optimizer.step()
     37         break

~/anaconda2/envs/tbd-env/lib/python3.6/site-packages/torch/tensor.py in backward(self, gradient, retain_graph, create_graph)
     91                 products. Defaults to ``False``.
     92         """
---> 93         torch.autograd.backward(self, gradient, retain_graph, create_graph)
     94 
     95     def register_hook(self, hook):

~/anaconda2/envs/tbd-env/lib/python3.6/site-packages/torch/autograd/__init__.py in backward(tensors, grad_tensors, retain_graph, create_graph, grad_variables)
     88     Variable._execution_engine.run_backward(
     89         tensors, grad_tensors, retain_graph, create_graph,
---> 90         allow_unreachable=True)  # allow_unreachable flag
     91 
     92 

RuntimeError: element 0 of tensors does not require grad and does not have a grad_fn

Pytorch is trying to backpropagate through a tensor with no grad_fn, but I wasn't able to find the problem yet.

`imresize` was removed in scipy 1.3

deprecated in 1.0; they suggest using straight PIL instead

Efficiency question about the model

Hey, I didn't run the code yet. But I noticed the code module_net.py process questions in a batch one by one, the batch only share the same stem and classifier module. Although this design is quite reasonable since different questions need different modules, I still worry about the efficiency of the training pharse. What's your setup while training (GPU number, batchsize, training time, etc..)? Do you have some advices on accelerating this? Thanks!

can not find file scripts/extract_features.py

Excuse me,Thanks for your great work.when I run this code ,It have a little question.

"python scripts/extract_features.py
--input_image_dir </path/to/CLEVR/images/train>
--output_h5_file </path/to/train_features.h5>
--model_stage 2"

I can not find file scripts/extract_features.py
could you help me?

evaluate error on val

Hello, when I evaluate on val datasets, the error appears, so what's wrong?

Traceback (most recent call last):
  File "eval.py", line 17, in <module>
    dest_dir=Path('/data'), batch_size=128)
  File "/home/dengwei/tbd-nets/utils/generate_programs.py", line 256, in generate_programs
    programs_pred = program_generator.reinforce_sample(questions_var)
  File "/home/dengwei/tbd-nets/utils/generate_programs.py", line 121, in reinforce_sample
    encoded = self.encoder(x)
  File "/home/dengwei/tbd-nets/utils/generate_programs.py", line 91, in encoder
    embed = self.encoder_embed(x)
  File "/usr/local/lib/python3.5/dist-packages/torch/nn/modules/module.py", line 325, in __call__
    result = self.forward(*input, **kwargs)
  File "/usr/local/lib/python3.5/dist-packages/torch/nn/modules/sparse.py", line 103, in forward
    self.scale_grad_by_freq, self.sparse
RuntimeError: save_for_backward can only save input or output tensors, but argument 0 doesn't satisfy this condition

and this is the place I changed in test-eval:

vocab_path = Path('data/vocab.json')
model_path = Path('models/clevr-reg-hres.pt')
tbd_net = load_tbd_net(model_path, load_vocab(vocab_path))

program_generator = load_program_generator(Path('models/program_generator.pt'))
generate_programs(Path('data/val_questions.h5'), program_generator, 
                  dest_dir=Path('/data'), batch_size=128)
                  
use_np_features = False
if use_np_features:
    features = np.load(str(Path('data/test/test_features.npy')), mmap_mode='r')
else:
    features = h5py.File(Path('data/val_features.h5'))['features']

question_np = np.load(Path('data/val_questions.npy'))
image_idx_np = np.load(Path('data/val_image_idxs.npy'))
programs_np = np.load(Path('data/val_programs.npy'))

Version bumps

I am able to run our demo on PyTorch 1.1, and I am sure we are Python 3.7 compatible. Can we bump our documented versions?

How to evaluate test results?

Hi,
After getting predicted answers for test data, how can I evaluate results?
Since there are different setting in your paper (e.g., Count, Compare, Exist, and so on), could u have code snippet to conveniently achieve this?
Thanks

What's the use of cat operation in SameModule

In SameModule, after the mul of feats and attended_feats，cross-correlation is done. So what's the use of cat operation? cat with attn, does it help?

The environment setting

I find that I am stuck with the environment settings. My system is Ubuntu 16.04 ,NVIDIA driver 384.111 cuda9.1 and GTX 1080 ti.
But the error with step 2 is "Cuda runtime error(25):CUDA driver version is insufficient for CUDA runtime version".
With the NVIDIA driver up to 387.26 or 390.42, Ubuntu cannot identity the NVIDIA driver.
Nevertheless with CUDA version down to 8, the other ImportError libcudart.so.9.1: cannot open shared object files.
So may I ask what's the environment setting appropriate for the recreation?

tensor matches error

My eval.py file copies from test-eval.ipynb

import torch

from pathlib import Path
import numpy as np
import h5py

from tbd.module_net import load_tbd_net
from utils.clevr import load_vocab
from utils.generate_programs import load_program_generator, generate_programs


vocab_path = Path('data/vocab.json')
model_path = Path('models/clevr-reg-hres.pt')
tbd_net = load_tbd_net(model_path, load_vocab(vocab_path))


program_generator = load_program_generator(Path('models/program_generator.pt'))
generate_programs(Path('data/val_questions.h5'), program_generator, 
                  dest_dir=Path('data/val/'), batch_size=128)


use_np_features = False
if use_np_features:
    features = np.load(str(Path('data/val/val_features.npy')), mmap_mode='r')
else:
    features = h5py.File(Path('data/val_features.h5'))['features']

question_np = np.load(Path('data/val/questions.npy'))
image_idx_np = np.load(Path('data/val/image_idxs.npy'))
programs_np = np.load(Path('data/val/programs.npy'))


answers = ['blue', 'brown', 'cyan', 'gray', 'green', 'purple', 'red', 'yellow',
           'cube', 'cylinder', 'sphere',
           'large', 'small',
           'metal', 'rubber',
           'no', 'yes',
           '0', '1', '10', '2', '3', '4', '5', '6', '7', '8', '9']

pred_idx_to_token = dict(zip(range(len(answers)), answers))


f = open('predicted_answers.txt', 'w')
def write_preds(preds):
    for pred in preds:
        f.write(pred)
        f.write('\n')



device = 'cuda' if torch.cuda.is_available() else 'cpu'



batch_size = 128
for batch in range(0, len(programs_np), batch_size):
    image_idx = image_idx_np[batch:batch+batch_size]
    programs = torch.LongTensor(programs_np[batch:batch+batch_size]).to(device)
    
    if use_np_features:
        feats = torch.FloatTensor(np.asarray(features[image_idx])).to(device)
    else:
        # Using HDF5 files requires some overhead due to constraints on how those may
        # be accessed. We cannot index into the file using a numpy array. We also cannot 
        # access the same element multiple times (e.g. we cannot index into an h5py.File 
        # with [1,1,1]) because we are constrained to increasing sequences
        feats = []
        for idx in image_idx:
            feats.append(np.asarray(features[idx]))
        feats = torch.FloatTensor(np.asarray(feats)).to(device)

    outputs = tbd_net(feats, programs)
    _, preds = outputs.max(1)
    preds = [pred_idx_to_token[pred] for pred in preds.detach().to('cpu').numpy()]
    write_preds(preds)
f.close()

and error as

Traceback (most recent call last):
  File "eval.py", line 72, in <module>
    outputs = tbd_net(feats, programs)
  File "/home/dengwei/anaconda3/lib/python3.6/site-packages/torch/nn/modules/module.py", line 491, in __call__
    result = self.forward(*input, **kwargs)
  File "/home/dengwei/tbd-nets/tbd/module_net.py", line 195, in forward
    output = module(feat_input, output)
  File "/home/dengwei/anaconda3/lib/python3.6/site-packages/torch/nn/modules/module.py", line 491, in __call__
    result = self.forward(*input, **kwargs)
  File "/home/dengwei/tbd-nets/tbd/modules.py", line 92, in forward
    attended_feats = torch.mul(feats, attn.repeat(1, self.dim, 1, 1))
RuntimeError: The size of tensor a (128) must match the size of tensor b (16384) at non-singleton dimension 1

maybe I should use NUMPY file rather HDF5 file?I extract feature from this master.