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Introduction

Language understanding is an ongoing challenge and one of the most relevant and influential areas across any industry.

“Bidirectional Encoder Representations from Transformers (BERT) is a new method of pre-training language representations which obtains state-of-the-art results on a wide array of Natural Language Processing (NLP) tasks. When BERT was originally published it achieved state-of-the-art performance in eleven natural language understanding tasks.

BERT is a method of pre-training language representations, meaning that we train a general-purpose "language understanding" model on a large text corpus (like Wikipedia), and then use that model for downstream NLP tasks that we care about (like question answering). BERT outperforms previous methods because it is the first unsupervised, deeply bidirectional system for pre-training NLP.

1  SQuAD 1.1 with Tensorflow BERT-BASE

1.1 About the application and benchmarks

This guide is to be used as a starting point.  It does not provide detailed guidance on optimizations and additional tuning.  Please follow the guidelines in the Competition Limits section of this document.

1.1.1  About BERT-BASE

BERT, or Bidirectional Encoder Representations from Transformers, is a new method of pre-training language representations which obtains state-of-the-art results on a wide array of Natural Language Processing (NLP) tasks.

BERT is a method of pre-training language representations, meaning that we train a general-purpose "language understanding" model on a large text corpus (like Wikipedia), and then use that model for downstream NLP tasks that we care about (like question answering). BERT outperforms previous methods because it is the first unsupervised, deeply bidirectional system for pre-training NLP.

BERT’s model architecture is a multi-layer bidirectional Transformer encoder based on the original implementation described in Vaswani et al. (2017) and released in the tensor2tensor library. The architecture of BERT is almost identical to the original Transformer. A good reference guides for its implementation is “The Annotated Transformer.”

The developer team denote the number of layers (i.e., Transformer blocks) as L, the hidden size as H, and the number of self-attention heads as A. The team primarily report results on two model sizes:

·       BERT-BASE (L=12, H=768, A=12, Total Parameters=110M) and

·       BERT-LARGE (L=24, H=1024, A=16, Total Parameters=340M)

BERT-BASE contains 110M parameters and BERT-LARGE contains 340M parameters.

For the purposes of this challenge, we will be using BERT-BASE.

1.1.2 About SQuAD 1.1

The Stanford Question Answering Dataset (SQuAD) is a popular question answering benchmark dataset. BERT (at the time of the release) obtains state-of-the-art results on SQuAD with almost no task-specific network architecture modifications or data augmentation. However, it does require semi-complex data pre-processing and post-processing to deal with (a) the variable-length nature of SQuAD context paragraphs, and (b) the character-level answer annotations which are used for SQuAD training. This processing is implemented and documented in run_squad.py.

1.2  Running SQuAD 1.1 fine tuning and inference

1.2.1  Using Docker and NVIDIA Docker Image

docker pull nvcr.io/nvidia/tensorflow:20.02-tf1-py3
docker images
REPOSITORY                                                       TAG                 IMAGE ID            CREATED             SIZE
nvcr.io/nvidia/tensorflow                                        20.02-tf1-py3       0c7b70421b78        7 weeks ago         9.49GB

Example of how to run the container:

Usage:  docker run [OPTIONS] IMAGE [COMMAND] [ARG...]

docker run -it --net=host -v bigdata:/bigdata 0c7b70421b78

1.2.2   Download the benchmark codes

Note: if you are using the docker container above, you already have the code and examples in /workspace/nvidia-examples/bert/ and can skip this step.

NVIDIA BERT codes is a publicly available implementation of BERT. It supports Multi-GPU training with Horovod - NVIDIA BERT fine-tune code uses Horovod to implement efficient multi-GPU training with NCCL.

[~]# git clone https://github.com/NVIDIA/DeepLearningExamples.git

You may use other implementations, optimize and tune; but you must use the BERT-Base uncased pre-trained model for the purposes of this challenge.

Some other examples include:

1.2.3  Download BERT-BASE model file

The BERT-BASE, Uncased model file contains 12-layer, 768-hidden, 12-heads, 110M parameters. Its download link can be found at https://github.com/google-research/bert

We will create directories and download to :

/workspace/nvidia-examples/bert/data/download/google_pretrained_weights

root@tessa002:/workspace/nvidia-examples/bert/data# mkdir download
root@tessa002:/workspace/nvidia-examples/bert/data# cd download
root@tessa002:/workspace/nvidia-examples/bert/data/download# mkdir google_pretrained_weights
root@tessa002:/workspace/nvidia-examples/bert/data/download# cd google_pretrained_weights/
root@tessa002:/workspace/nvidia-examples/bert/data/download/google_pretrained_weights# wget https://storage.googleapis.com/bert_models/2018_10_18/uncased_L-12_H-768_A-12.zip
root@tessa002:/workspace/nvidia-examples/bert/data/download/google_pretrained_weights# unzip uncased_L-12_H-768_A-12.zip
Archive:  uncased_L-12_H-768_A-12.zip
   creating: uncased_L-12_H-768_A-12/
  inflating: uncased_L-12_H-768_A-12/bert_model.ckpt.meta
  inflating: uncased_L-12_H-768_A-12/bert_model.ckpt.data-00000-of-00001
  inflating: uncased_L-12_H-768_A-12/vocab.txt
  inflating: uncased_L-12_H-768_A-12/bert_model.ckpt.index
  inflating: uncased_L-12_H-768_A-12/bert_config.json

1.2.4   Download the SQuAD 1.1 dataset

To run on SQuAD, you will first need to download the dataset. The SQuAD website does not seem to link to the v1.1 datasets any longer, but the necessary files can be found here:

We will download these to: /workspace/nvidia-examples/bert/data/download/squad/v1.1

root@tessa002:/workspace/nvidia-examples/bert/data/download# mkdir squad
root@tessa002:/workspace/nvidia-examples/bert/data/download# cd squad
root@tessa002:/workspace/nvidia-examples/bert/data/download/squad# mkdir v1.1
root@tessa002:/workspace/nvidia-examples/bert/data/download/squad# cd v1.1/
root@tessa002:/workspace/nvidia-examples/bert/data/download/squad/v1.1# wget https://rajpurkar.github.io/SQuAD-explorer/dataset/train-v1.1.json
root@tessa002:/workspace/nvidia-examples/bert/data/download/squad/v1.1# wget https://rajpurkar.github.io/SQuAD-explorer/dataset/dev-v1.1.json
root@tessa002:/workspace/nvidia-examples/bert/data/download/squad/v1.1#  wget https://github.com/allenai/bi-att-flow/archive/master.zip
root@tessa002:/workspace/nvidia-examples/bert/data/download/squad/v1.1# unzip master.zip
root@tessa002:/workspace/nvidia-examples/bert/data/download/squad/v1.1# cd bi-att-flow-master/
root@tessa002:/workspace/nvidia-examples/bert/data/download/squad/v1.1/bi-att-flow-master# cd squad
root@tessa002:/workspace/nvidia-examples/bert/data/download/squad/v1.1/bi-att-flow-master/squad# cp evaluate-v1.1.py /workspace/nvidia-examples/bert/data/download/squad/v1.1/
root@tessa002:cd /workspace/nvidia-examples/bert

1.2.5   Start fine tuning

BERT representations can be fine tuned with just one additional output layer for a state-of-the-art Question Answering system. From within the container, you can use the following script to run fine-training for SQuAD.

Note : consider logging results with “>2&1 tee $LOGFILE” for submissions to judges

For SQuAD 1.1 FP16 training with XLA using a DGX-1 with (8) V100 32G, run:

bash scripts/run_squad.sh 10 5e-6 fp16 true 8 384 128 base 1.1 data/download/google_pretrained_weights/uncased_L-12_H-768_A-12/bert_model.ckpt 1.1

For SQuAD 1.1 FP16 training with XLA using (4) T4 16GB GPU's run:

bash scripts/run_squad.sh 10 5e-6 fp16 true 4 384 128 base 1.1 data/download/google_pretrained_weights/uncased_L-12_H-768_A-12/bert_model.ckpt 1.1

1.2.6  Verify results

INFO:tensorflow:-----------------------------
I0326 01:25:43.144953 140630939256640 run_squad.py:1127] -----------------------------
INFO:tensorflow:Total Inference Time = 88.62 for Sentences = 10840
I0326 01:25:43.145423 140630939256640 run_squad.py:1129] Total Inference Time = 88.62 for Sentences = 10840
INFO:tensorflow:Total Inference Time W/O Overhead = 75.86 for Sentences = 10824
I0326 01:25:43.145554 140630939256640 run_squad.py:1131] Total Inference Time W/O Overhead = 75.86 for Sentences = 10824
INFO:tensorflow:Summary Inference Statistics
I0326 01:25:43.145649 140630939256640 run_squad.py:1132] Summary Inference Statistics
INFO:tensorflow:Batch size = 8
I0326 01:25:43.145738 140630939256640 run_squad.py:1133] Batch size = 8
INFO:tensorflow:Sequence Length = 384
I0326 01:25:43.145867 140630939256640 run_squad.py:1134] Sequence Length = 384
INFO:tensorflow:Precision = fp16
I0326 01:25:43.145962 140630939256640 run_squad.py:1135] Precision = fp16
INFO:tensorflow:Latency Confidence Level 50 (ms) = 55.79
I0326 01:25:43.146052 140630939256640 run_squad.py:1136] Latency Confidence Level 50 (ms) = 55.79
INFO:tensorflow:Latency Confidence Level 90 (ms) = 57.03
I0326 01:25:43.146145 140630939256640 run_squad.py:1137] Latency Confidence Level 90 (ms) = 57.03
INFO:tensorflow:Latency Confidence Level 95 (ms) = 57.29
I0326 01:25:43.146225 140630939256640 run_squad.py:1138] Latency Confidence Level 95 (ms) = 57.29
INFO:tensorflow:Latency Confidence Level 99 (ms) = 58.62
I0326 01:25:43.146308 140630939256640 run_squad.py:1139] Latency Confidence Level 99 (ms) = 58.62
INFO:tensorflow:Latency Confidence Level 100 (ms) = 286.80
I0326 01:25:43.146387 140630939256640 run_squad.py:1140] Latency Confidence Level 100 (ms) = 286.80
INFO:tensorflow:Latency Average (ms) = 56.07
I0326 01:25:43.146471 140630939256640 run_squad.py:1141] Latency Average (ms) = 56.07
INFO:tensorflow:Throughput Average (sentences/sec) = 142.68
I0326 01:25:43.146564 140630939256640 run_squad.py:1142] Throughput Average (sentences/sec) = 142.68
INFO:tensorflow:-----------------------------
I0326 01:25:43.146645 140630939256640 run_squad.py:1143] -----------------------------
INFO:tensorflow:Writing predictions to: /results/tf_bert_finetuning_squad_base_fp16_gbs40_200326010711/predictions.json
I0326 01:25:43.146801 140630939256640 run_squad.py:431] Writing predictions to: /results/tf_bert_finetuning_squad_base_fp16_gbs40_200326010711/predictions.json
INFO:tensorflow:Writing nbest to: /results/tf_bert_finetuning_squad_base_fp16_gbs40_200326010711/nbest_predictions.json
I0326 01:25:43.146886 140630939256640 run_squad.py:432] Writing nbest to: /results/tf_bert_finetuning_squad_base_fp16_gbs40_200326010711/nbest_predictions.json
{"exact_match": 78.0321665089877, "f1": 86.34229152935384}

Note : part of your final score includes these results:

{"exact_match": 78.0321665089877, "f1": 86.34229152935384}

1.2.7  (Optional) Alternative method with Lambda Labs

root@tessa002:/workspace# mkdir lambdal
root@tessa002:/workspace# cd lambdal
root@tessa002:/workspace/lambdal# git clone https://github.com/lambdal/bert
root@tessa002:/workspace/lambdal/bert# mpirun -np 4 -H localhost:4 -bind-to none -map-by slot -x NCCL_DEBUG=INFO -x LD_LIBRARY_PATH -x PATH -mca pml ob1 -mca btl ^openib --allow-run-as-root python3 run_squad_hvd.py --vocab_file=/workspace/nvidia-examples/bert/data/download/google_pretrained_weights/uncased_L-12_H-768_A-12/vocab.txt   --bert_config_file=/workspace/nvidia-examples/bert/data/download/google_pretrained_weights/uncased_L-12_H-768_A-12/bert_config.json   --init_checkpoint=/workspace/nvidia-examples/bert/data/download/google_pretrained_weights/uncased_L-12_H-768_A-12/bert_model.ckpt  --do_train=True   --train_file=/workspace/nvidia-examples/bert/data/download/squad/v1.1/train-v1.1.json   --do_predict=True   --predict_file=/workspace/nvidia-examples/bert/data/download/squad/v1.1/dev-v1.1.json --train_batch_size=12 --learning_rate=3e-5   --num_train_epochs=2.0   --max_seq_length=384   --doc_stride=128   --output_dir=/results/lambdal/squad1/squad_base/ --horovod=true

look for similar output

I0326 05:55:19.917063 140421161031488 run_squad_hvd.py:747] Writing predictions to: /results/lambdal/squad1/squad_base/predictions.json
INFO:tensorflow:Writing nbest to: /results/lambdal/squad1/squad_base/nbest_predictions.json
I0326 05:55:19.917179 140421161031488 run_squad_hvd.py:748] Writing nbest to: /results/lambdal/squad1/squad_base/nbest_predictions.json

To check score:

root@tessa002:/workspace/lambdal/bert# python /workspace/nvidia-examples/bert/data/download/squad/v1.1/evaluate-v1.1.py /workspace/nvidia-examples/bert/data/download/squad/v1.1/dev-v1.1.json /results/lambdal/squad1/squad_base/predictions.json
{"exact_match": 78.1929990539262, "f1": 86.51319484763773}

Note : part of your final score includes these results:

{"exact_match": 78.1929990539262, "f1": 86.51319484763773}

1.2.8  Example predict Q&A on real data with - github.com/google-research/bert

Note : This is the method that judges will use to score unseen data

root@tessa002:/workspace/nvidia-examples/bert# cd /workspace
root@tessa002:/workspace# git clone https://github.com/google-research/bert.git
root@tessa002:/workspace# cd bert

1.2.9  Create a sample input file

Create a simple input file, save as test_input.json in json format (note the "id" to reference later).

Using vi editor should automatically handle the formatting of json, or switch to paste mode (:set paste -> [paste text] -> :set nopaste):

{
    "version": "v1.1",
    "data": [
        {
            "title": "your_title",
            "paragraphs": [
                {
                    "qas": [
                        {
                            "question": "Who is current CEO?",
                            "id": "56ddde6b9a695914005b9628",
                            "is_impossible": ""
                        },
                        {
                            "question": "Who founded google?",
                            "id": "56ddde6b9a695914005b9629",
                            "is_impossible": ""
                        },
                        {
                            "question": "when did IPO take place?",
                            "id": "56ddde6b9a695914005b962a",
                            "is_impossible": ""
                        }
                    ],
                    "context": "Google was founded in 1998 by Larry Page and Sergey Brin while they were Ph.D. students at Stanford University in California. Together they own about 14 percent of its shares and control 56 percent of the stockholder voting power through supervoting stock. They incorporated Google as a privately held company on September 4, 1998. An initial public offering (IPO) took place on August 19, 2004, and Google moved to its headquarters in Mountain View, California, nicknamed the Googleplex. In August 2015, Google announced plans to reorganize its various interests as a conglomerate called Alphabet Inc. Google is Alphabet's leading subsidiary and will continue to be the umbrella company for Alphabet's Internet interests. Sundar Pichai was appointed CEO of Google, replacing Larry Page who became the CEO of Alphabet."                
                 }
            ]
        }
    ]
}


1.2.10  Run run_squad.py as do-predict=true using fine-tuned model checkpoint :

root@tessa002:/workspace/bert# python3 run_squad.py --vocab_file=/workspace/nvidia-examples/bert/data/download/google_pretrained_weights/uncased_L-12_H-768_A-12/vocab.txt --bert_config_file=/workspace/nvidia-examples/bert/data/download/google_pretrained_weights/uncased_L-12_H-768_A-12/bert_config.json   --init_checkpoint=/results/tf_bert_finetuning_squad_base_fp16_gbs40_200326010711/model.ckpt-2408  --do_train=False --max_query_length=30 --do_predict=True   --predict_file=test_input.json --predict_batch_size=16 --max_seq_length=384 --doc_stride=128 --output_dir=/results/squad1/squad_test/


Note:  If you are using alternative method from Lamda Labs, you will need to use that checkpoint :

root@tessa002:/workspace/lambdal/bert# python3 run_squad.py --vocab_file=/workspace/nvidia-examples/bert/data/download/google_pretrained_weights/uncased_L-12_H-768_A-12/vocab.txt --bert_config_file=/workspace/nvidia-examples/bert/data/download/google_pretrained_weights/uncased_L-12_H-768_A-12/bert_config.json   --init_checkpoint=/results/lambdal/squad1/squad_base/model.ckpt-3649  --do_train=False --max_query_length=30 --do_predict=True   --predict_file=test_input.json --predict_batch_size=16 --max_seq_length=384 --doc_stride=128 --output_dir=/results/lambdal/squad1/squad_test/

1.2.11  You should see similar output below :

I0326 02:11:40.096473 140685488179008 run_squad.py:1259] Processing example: 0
INFO:tensorflow:prediction_loop marked as finished
I0326 02:11:40.165820 140685488179008 error_handling.py:101] prediction_loop marked as finished
INFO:tensorflow:prediction_loop marked as finished
I0326 02:11:40.166095 140685488179008 error_handling.py:101] prediction_loop marked as finished
INFO:tensorflow:Writing predictions to: /results/squad1/squad_test/predictions.json
I0326 02:11:40.166555 140685488179008 run_squad.py:745] Writing predictions to: /results/squad1/squad_test/predictions.json
INFO:tensorflow:Writing nbest to: /results/squad1/squad_test/nbest_predictions.json
I0326 02:11:40.166669 140685488179008 run_squad.py:746] Writing nbest to: /results/squad1/squad_test/nbest_predictions.json

1.2.12  Check correctness in file :  predictions.json

{
    "56ddde6b9a695914005b9628": "Sundar Pichai",
    "56ddde6b9a695914005b9629": "Larry Page and Sergey Brin",
    "56ddde6b9a695914005b9630": "September 4, 1998",
    "56ddde6b9a695914005b9631": "CEO",
    "56ddde6b9a695914005b9632": "Alphabet Inc"
}

1.2.13  Check accuracy in file:  nbest_predictions.json

{
    "56ddde6b9a695914005b9628": [
        {
            "text": "Sundar Pichai",
            "probability": 0.6877274611974046,
            "start_logit": 7.016119003295898,
            "end_logit": 6.917689323425293
        },
        {
            "text": "Sundar Pichai was appointed CEO of Google, replacing Larry Page",
            "probability": 0.27466839794889614,
            "start_logit": 7.016119003295898,
            "end_logit": 5.999861240386963
        },
        {
            "text": "Larry Page",
            "probability": 0.02874494871571203,
            "start_logit": 4.759016513824463,
            "end_logit": 5.999861240386963
        },

Note :  Part of your final score is based on inferencing unseen data; which will be provided by the judges on the day of the challenge. 

Scores will be derived from the nbest_predictions.json output for each question on the context.

1.3  Challenge Limitation

  • Must stick to pre-defined model (BERT-Base, Uncased)

  • Teams can locally cache (on SSD) starting model weights and dataset

  • HuggingFace implementation (TensorFlow/PyTorch) is the official standard. Usage of other implementation, or modification to official, is subject to approval.

  • Teams are allowed to explore different optimizers (SGD/Adam etc.) or learning rate schedules, or any other techniques that do not modify model architecture.

  • Teams are not allowed to modify any model hyperparameters or add additional layers.

  • Entire model must be fine-tuned (cannot freeze layers)

  • You must provide all scripts and methodology used to achieve results

1.4  Teams must produce

  • Training scripts with their full training routine and command lines and output

  • Evaluation-only script for verification of result. Final evaluation is on a fixed sequence length (128 tokens).

  • Final model ckpt and inference files

  • Team’s training scripts and methodology, command line and logs of runs

  • run_squad.py predictions.json and nbest_predictions.json

1.5  Final Scoring

The judges will score with standard evaluate-v1.1.py from Squad 1.1

 i.e. {"exact_match": 81.01229895931883, "f1": 88.61239393038589}

Final scores from unseen data of multiple questions; prediction from file, using standard run_squad.py

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