Grammatical Error Correction with OpenVINO

This Jupyter notebook can be launched after a local installation only.

Github

AI-based auto-correction products are becoming increasingly popular due to their ease of use, editing speed, and affordability. These products improve the quality of written text in emails, blogs, and chats.

Grammatical Error Correction (GEC) is the task of correcting different types of errors in text such as spelling, punctuation, grammatical and word choice errors. GEC is typically formulated as a sentence correction task. A GEC system takes a potentially erroneous sentence as input and is expected to transform it into a more correct version. See the example given below:

Input (Erroneous)

Output (Corrected)

I like to rides my bicycle.

I like to ride my bicycle.

As shown in the image below, different types of errors in written language can be corrected.

error_types

error_types

This tutorial shows how to perform grammatical error correction using OpenVINO. We will use pre-trained models from the Hugging Face Transformers library. To simplify the user experience, the Hugging Face Optimum library is used to convert the models to OpenVINO™ IR format.

It consists of the following steps:

  • Install prerequisites

  • Download and convert models from a public source using the OpenVINO integration with Hugging Face Optimum.

  • Create an inference pipeline for grammatical error checking

  • Optimize grammar correction pipeline with NNCF quantization

  • Compare original and optimized pipelines from performance and accuracy standpoints

Table of contents:

How does it work?

A Grammatical Error Correction task can be thought of as a sequence-to-sequence task where a model is trained to take a grammatically incorrect sentence as input and return a grammatically correct sentence as output. We will use the FLAN-T5 model finetuned on an expanded version of the JFLEG dataset.

The version of FLAN-T5 released with the Scaling Instruction-Finetuned Language Models paper is an enhanced version of T5 that has been finetuned on a combination of tasks. The paper explores instruction finetuning with a particular focus on scaling the number of tasks, scaling the model size, and finetuning on chain-of-thought data. The paper discovers that overall instruction finetuning is a general method that improves the performance and usability of pre-trained language models.

flan-t5_training

flan-t5_training

For more details about the model, please check out paper, original repository, and Hugging Face model card

Additionally, to reduce the number of sentences required to be processed, you can perform grammatical correctness checking. This task should be considered as a simple binary text classification, where the model gets input text and predicts label 1 if a text contains any grammatical errors and 0 if it does not. You will use the roberta-base-CoLA model, the RoBERTa Base model finetuned on the CoLA dataset. The RoBERTa model was proposed in RoBERTa: A Robustly Optimized BERT Pretraining Approach paper. It builds on BERT and modifies key hyperparameters, removing the next-sentence pre-training objective and training with much larger mini-batches and learning rates. Additional details about the model can be found in a blog post by Meta AI and in the Hugging Face documentation

Now that we know more about FLAN-T5 and RoBERTa, let us get started. 🚀

Prerequisites

First, we need to install the Hugging Face Optimum library accelerated by OpenVINO integration. The Hugging Face Optimum API is a high-level API that enables us to convert and quantize models from the Hugging Face Transformers library to the OpenVINO™ IR format. For more details, refer to the Hugging Face Optimum documentation.

%pip install -q "git+https://github.com/huggingface/optimum-intel.git" "openvino>=2023.1.0" onnx gradio "transformers>=4.33.0" --extra-index-url https://download.pytorch.org/whl/cpu
%pip install -q "nncf>=2.7.0" datasets jiwer
Note: you may need to restart the kernel to use updated packages.
Note: you may need to restart the kernel to use updated packages.

Download and Convert Models

Optimum Intel can be used to load optimized models from the Hugging Face Hub and create pipelines to run an inference with OpenVINO Runtime using Hugging Face APIs. The Optimum Inference models are API compatible with Hugging Face Transformers models. This means we just need to replace AutoModelForXxx class with the corresponding OVModelForXxx class.

Below is an example of the RoBERTa text classification model

-from transformers import AutoModelForSequenceClassification
+from optimum.intel.openvino import OVModelForSequenceClassification
from transformers import AutoTokenizer, pipeline

model_id = "textattack/roberta-base-CoLA"
-model = AutoModelForSequenceClassification.from_pretrained(model_id)
+model = OVModelForSequenceClassification.from_pretrained(model_id, from_transformers=True)

Model class initialization starts with calling from_pretrained method. When downloading and converting Transformers model, the parameter from_transformers=True should be added. We can save the converted model for the next usage with the save_pretrained method. Tokenizer class and pipelines API are compatible with Optimum models.

from pathlib import Path
from transformers import pipeline, AutoTokenizer
from optimum.intel.openvino import OVModelForSeq2SeqLM, OVModelForSequenceClassification
2023-09-27 14:53:36.462575: I tensorflow/core/util/port.cc:110] oneDNN custom operations are on. You may see slightly different numerical results due to floating-point round-off errors from different computation orders. To turn them off, set the environment variable TF_ENABLE_ONEDNN_OPTS=0.
2023-09-27 14:53:36.496914: I tensorflow/core/platform/cpu_feature_guard.cc:182] This TensorFlow binary is optimized to use available CPU instructions in performance-critical operations.
To enable the following instructions: AVX2 AVX512F AVX512_VNNI FMA, in other operations, rebuild TensorFlow with the appropriate compiler flags.
2023-09-27 14:53:37.063292: W tensorflow/compiler/tf2tensorrt/utils/py_utils.cc:38] TF-TRT Warning: Could not find TensorRT
INFO:nncf:NNCF initialized successfully. Supported frameworks detected: torch, tensorflow, onnx, openvino
No CUDA runtime is found, using CUDA_HOME='/usr/local/cuda-11.7'
/home/nsavel/venvs/ov_notebooks_tmp/lib/python3.8/site-packages/transformers/deepspeed.py:23: FutureWarning: transformers.deepspeed module is deprecated and will be removed in a future version. Please import deepspeed modules directly from transformers.integrations
  warnings.warn(

Select inference device

select device from dropdown list for running inference using OpenVINO

import ipywidgets as widgets
import openvino as ov

core = ov.Core()

device = widgets.Dropdown(
    options=core.available_devices + ["AUTO"],
    value='AUTO',
    description='Device:',
    disabled=False,
)

device
Dropdown(description='Device:', index=1, options=('CPU', 'AUTO'), value='AUTO')

Grammar Checker

grammar_checker_model_id = "textattack/roberta-base-CoLA"
grammar_checker_dir = Path("roberta-base-cola")
grammar_checker_tokenizer = AutoTokenizer.from_pretrained(grammar_checker_model_id)

if grammar_checker_dir.exists():
    grammar_checker_model = OVModelForSequenceClassification.from_pretrained(grammar_checker_dir, device=device.value)
else:
    grammar_checker_model = OVModelForSequenceClassification.from_pretrained(grammar_checker_model_id, export=True, device=device.value, load_in_8bit=False)
    grammar_checker_model.save_pretrained(grammar_checker_dir)
Framework not specified. Using pt to export to ONNX.
Some weights of the model checkpoint at textattack/roberta-base-CoLA were not used when initializing RobertaForSequenceClassification: ['roberta.pooler.dense.weight', 'roberta.pooler.dense.bias']
- This IS expected if you are initializing RobertaForSequenceClassification from the checkpoint of a model trained on another task or with another architecture (e.g. initializing a BertForSequenceClassification model from a BertForPreTraining model).
- This IS NOT expected if you are initializing RobertaForSequenceClassification from the checkpoint of a model that you expect to be exactly identical (initializing a BertForSequenceClassification model from a BertForSequenceClassification model).
Using framework PyTorch: 1.13.1+cpu
Overriding 1 configuration item(s)
    - use_cache -> False
WARNING:tensorflow:Please fix your imports. Module tensorflow.python.training.tracking.base has been moved to tensorflow.python.trackable.base. The old module will be deleted in version 2.11.
[ WARNING ]  Please fix your imports. Module %s has been moved to %s. The old module will be deleted in version %s.
Compiling the model to CPU ...
Set CACHE_DIR to /tmp/tmpcqv99eqb/model_cache

Let us check model work, using inference pipeline for text-classification task. You can find more information about usage Hugging Face inference pipelines in this tutorial

input_text = "They are moved by salar energy"
grammar_checker_pipe = pipeline("text-classification", model=grammar_checker_model, tokenizer=grammar_checker_tokenizer)
result = grammar_checker_pipe(input_text)[0]
print(f"input text: {input_text}")
print(f'predicted label: {"contains_errors" if result["label"] == "LABEL_1" else "no errors"}')
print(f'predicted score: {result["score"] :.2}')
input text: They are moved by salar energy
predicted label: contains_errors
predicted score: 0.88

Great! Looks like the model can detect errors in the sample.

Grammar Corrector

The steps for loading the Grammar Corrector model are very similar, except for the model class that is used. Because FLAN-T5 is a sequence-to-sequence text generation model, we should use the OVModelForSeq2SeqLM class and the text2text-generation pipeline to run it.

grammar_corrector_model_id = "pszemraj/flan-t5-large-grammar-synthesis"
grammar_corrector_dir = Path("flan-t5-large-grammar-synthesis")
grammar_corrector_tokenizer = AutoTokenizer.from_pretrained(grammar_corrector_model_id)

if grammar_corrector_dir.exists():
    grammar_corrector_model = OVModelForSeq2SeqLM.from_pretrained(grammar_corrector_dir, device=device.value)
else:
    grammar_corrector_model = OVModelForSeq2SeqLM.from_pretrained(grammar_corrector_model_id, export=True, device=device.value)
    grammar_corrector_model.save_pretrained(grammar_corrector_dir)
Framework not specified. Using pt to export to ONNX.
Using framework PyTorch: 1.13.1+cpu
Overriding 1 configuration item(s)
    - use_cache -> False
Using framework PyTorch: 1.13.1+cpu
Overriding 1 configuration item(s)
    - use_cache -> True
/home/nsavel/venvs/ov_notebooks_tmp/lib/python3.8/site-packages/transformers/modeling_utils.py:875: TracerWarning: Converting a tensor to a Python boolean might cause the trace to be incorrect. We can't record the data flow of Python values, so this value will be treated as a constant in the future. This means that the trace might not generalize to other inputs!
  if causal_mask.shape[1] < attention_mask.shape[1]:
Using framework PyTorch: 1.13.1+cpu
Overriding 1 configuration item(s)
    - use_cache -> True
/home/nsavel/venvs/ov_notebooks_tmp/lib/python3.8/site-packages/transformers/models/t5/modeling_t5.py:509: TracerWarning: Converting a tensor to a Python boolean might cause the trace to be incorrect. We can't record the data flow of Python values, so this value will be treated as a constant in the future. This means that the trace might not generalize to other inputs!
  elif past_key_value.shape[2] != key_value_states.shape[1]:
Compiling the encoder to AUTO ...
Compiling the decoder to AUTO ...
Compiling the decoder to AUTO ...
grammar_corrector_pipe = pipeline("text2text-generation", model=grammar_corrector_model, tokenizer=grammar_corrector_tokenizer)
result = grammar_corrector_pipe(input_text)[0]
print(f"input text:     {input_text}")
print(f'generated text: {result["generated_text"]}')
/home/nsavel/venvs/ov_notebooks_tmp/lib/python3.8/site-packages/optimum/intel/openvino/modeling_seq2seq.py:339: FutureWarning: shared_memory is deprecated and will be removed in 2024.0. Value of shared_memory is going to override share_inputs value. Please use only share_inputs explicitly.
  last_hidden_state = torch.from_numpy(self.request(inputs, shared_memory=True)["last_hidden_state"]).to(
/home/nsavel/venvs/ov_notebooks_tmp/lib/python3.8/site-packages/optimum/intel/openvino/modeling_seq2seq.py:416: FutureWarning: shared_memory is deprecated and will be removed in 2024.0. Value of shared_memory is going to override share_inputs value. Please use only share_inputs explicitly.
  self.request.start_async(inputs, shared_memory=True)
input text:     They are moved by salar energy
generated text: They are powered by solar energy.

Nice! The result looks pretty good!

Prepare Demo Pipeline

Now let us put everything together and create the pipeline for grammar correction. The pipeline accepts input text, verifies its correctness, and generates the correct version if required. It will consist of several steps:

  1. Split text on sentences.

  2. Check grammatical correctness for each sentence using Grammar Checker.

  3. Generate an improved version of the sentence if required.

import re
import transformers
from tqdm.notebook import tqdm


def split_text(text: str) -> list:
    """
    Split a string of text into a list of sentence batches.

    Parameters:
    text (str): The text to be split into sentence batches.

    Returns:
    list: A list of sentence batches. Each sentence batch is a list of sentences.
    """
    # Split the text into sentences using regex
    sentences = re.split(r"(?<=[^A-Z].[.?]) +(?=[A-Z])", text)

    # Initialize a list to store the sentence batches
    sentence_batches = []

    # Initialize a temporary list to store the current batch of sentences
    temp_batch = []

    # Iterate through the sentences
    for sentence in sentences:
        # Add the sentence to the temporary batch
        temp_batch.append(sentence)

        # If the length of the temporary batch is between 2 and 3 sentences, or if it is the last batch, add it to the list of sentence batches
        if len(temp_batch) >= 2 and len(temp_batch) <= 3 or sentence == sentences[-1]:
            sentence_batches.append(temp_batch)
            temp_batch = []

    return sentence_batches


def correct_text(text: str, checker: transformers.pipelines.Pipeline, corrector: transformers.pipelines.Pipeline, separator: str = " ") -> str:
    """
    Correct the grammar in a string of text using a text-classification and text-generation pipeline.

    Parameters:
    text (str): The inpur text to be corrected.
    checker (transformers.pipelines.Pipeline): The text-classification pipeline to use for checking the grammar quality of the text.
    corrector (transformers.pipelines.Pipeline): The text-generation pipeline to use for correcting the text.
    separator (str, optional): The separator to use when joining the corrected text into a single string. Default is a space character.

    Returns:
    str: The corrected text.
    """
    # Split the text into sentence batches
    sentence_batches = split_text(text)

    # Initialize a list to store the corrected text
    corrected_text = []

    # Iterate through the sentence batches
    for batch in tqdm(
        sentence_batches, total=len(sentence_batches), desc="correcting text.."
    ):
        # Join the sentences in the batch into a single string
        raw_text = " ".join(batch)

        # Check the grammar quality of the text using the text-classification pipeline
        results = checker(raw_text)

        # Only correct the text if the results of the text-classification are not LABEL_1 or are LABEL_1 with a score below 0.9
        if results[0]["label"] != "LABEL_1" or (
            results[0]["label"] == "LABEL_1" and results[0]["score"] < 0.9
        ):
            # Correct the text using the text-generation pipeline
            corrected_batch = corrector(raw_text)
            corrected_text.append(corrected_batch[0]["generated_text"])
        else:
            corrected_text.append(raw_text)

    # Join the corrected text into a single string
    corrected_text = separator.join(corrected_text)

    return corrected_text

Let us see it in action.

default_text = (
    "Most of the course is about semantic or  content of language but there are also interesting"
    " topics to be learned from the servicefeatures except statistics in characters in documents.At"
    " this point, He introduces herself as his native English speaker and goes on to say that if"
    " you contine to work on social scnce"
)

corrected_text = correct_text(default_text, grammar_checker_pipe, grammar_corrector_pipe)
huggingface/tokenizers: The current process just got forked, after parallelism has already been used. Disabling parallelism to avoid deadlocks...
To disable this warning, you can either:
    - Avoid using tokenizers before the fork if possible
    - Explicitly set the environment variable TOKENIZERS_PARALLELISM=(true | false)
correcting text..:   0%|          | 0/1 [00:00<?, ?it/s]
print(f"input text:     {default_text}\n")
print(f'generated text: {corrected_text}')
input text:     Most of the course is about semantic or  content of language but there are also interesting topics to be learned from the servicefeatures except statistics in characters in documents.At this point, He introduces herself as his native English speaker and goes on to say that if you contine to work on social scnce

generated text: Most of the course is about the semantic content of language but there are also interesting topics to be learned from the service features except statistics in characters in documents. At this point, she introduces herself as a native English speaker and goes on to say that if you continue to work on social science, you will continue to be successful.

Quantization

NNCF enables post-training quantization by adding quantization layers into model graph and then using a subset of the training dataset to initialize the parameters of these additional quantization layers. Quantized operations are executed in INT8 instead of FP32/FP16 making model inference faster.

Grammar checker model takes up a tiny portion of the whole text correction pipeline so we optimize only the grammar corrector model. Grammar corrector itself consists of three models: encoder, first call decoder and decoder with past. The last model’s share of inference dominates the other ones. Because of this we quantize only it.

The optimization process contains the following steps:

  1. Create a calibration dataset for quantization.

  2. Run nncf.quantize() to obtain quantized models.

  3. Serialize the INT8 model using openvino.save_model() function.

Please select below whether you would like to run quantization to improve model inference speed.

to_quantize = widgets.Checkbox(
    value=True,
    description='Quantization',
    disabled=False,
)

to_quantize
Checkbox(value=True, description='Quantization')

Run Quantization

Below we retrieve the quantized model. Please see utils.py for source code. Quantization is relatively time-consuming and will take some time to complete.

from utils import get_quantized_pipeline

grammar_corrector_pipe_fp32 = grammar_corrector_pipe
grammar_corrector_pipe_int8 = None
if to_quantize.value:
    quantized_model_path = Path("quantized_decoder_with_past") / "openvino_model.xml"
    grammar_corrector_pipe_int8 = get_quantized_pipeline(grammar_corrector_pipe_fp32, grammar_corrector_tokenizer, core, grammar_corrector_dir,
                                                         quantized_model_path, device.value)
Collecting calibration data:   0%|          | 0/10 [00:00<?, ?it/s]
/home/nsavel/workspace/openvino_notebooks/notebooks/214-grammar-correction/utils.py:39: FutureWarning: shared_memory is deprecated and will be removed in 2024.0. Value of shared_memory is going to override share_inputs value. Please use only share_inputs explicitly.
  return original_fn(*args, **kwargs)
Output()
Output()
Output()
Compiling the encoder to AUTO ...
Compiling the decoder to AUTO ...
Compiling the decoder to AUTO ...
Compiling the decoder to AUTO ...

Let’s see correction results. The generated texts for quantized INT8 model and original FP32 model should be almost the same.

if to_quantize.value:
    corrected_text_int8 = correct_text(default_text, grammar_checker_pipe, grammar_corrector_pipe_int8)
    print(f"Input text:                   {default_text}\n")
    print(f'Generated text by INT8 model: {corrected_text_int8}')
correcting text..:   0%|          | 0/1 [00:00<?, ?it/s]
Input text:                   Most of the course is about semantic or  content of language but there are also interesting topics to be learned from the servicefeatures except statistics in characters in documents.At this point, He introduces herself as his native English speaker and goes on to say that if you contine to work on social scnce

Generated text by INT8 model: Most of the course is about the semantic content of language but there are also interesting topics to be learned from the service features except statistics in characters in documents. At this point, she introduces himself as a native English speaker and goes on to say that if you continue to work on social issues, you will continue to be successful.

Compare model size, performance and accuracy

First, we compare file size of FP32 and INT8 models.

from utils import calculate_compression_rate

if to_quantize.value:
    model_size_fp32, model_size_int8 = calculate_compression_rate(grammar_corrector_dir / "openvino_decoder_with_past_model.xml", quantized_model_path)
Model footprint comparison:
    * FP32 IR model size: 1658150.26 KB
    * INT8 IR model size: 415713.38 KB

Second, we compare two grammar correction pipelines from performance and accuracy stand points.

Test split of jflegdataset is used for testing. One dataset sample consists of a text with errors as input and several corrected versions as labels. When measuring accuracy we use mean (1 - WER) against corrected text versions, where WER is Word Error Rate metric.

from utils import calculate_inference_time_and_accuracy

TEST_SUBSET_SIZE = 50

if to_quantize.value:
    inference_time_fp32, accuracy_fp32 = calculate_inference_time_and_accuracy(grammar_corrector_pipe_fp32, TEST_SUBSET_SIZE)
    print(f"Evaluation results of FP32 grammar correction pipeline. Accuracy: {accuracy_fp32:.2f}%. Time: {inference_time_fp32:.2f} sec.")
    inference_time_int8, accuracy_int8 = calculate_inference_time_and_accuracy(grammar_corrector_pipe_int8, TEST_SUBSET_SIZE)
    print(f"Evaluation results of INT8 grammar correction pipeline. Accuracy: {accuracy_int8:.2f}%. Time: {inference_time_int8:.2f} sec.")
    print(f"Performance speedup: {inference_time_fp32 / inference_time_int8:.3f}")
    print(f"Accuracy drop :{accuracy_fp32 - accuracy_int8:.2f}%.")
    print(f"Model footprint reduction: {model_size_fp32 / model_size_int8:.3f}")
Evaluation:   0%|          | 0/50 [00:00<?, ?it/s]
Evaluation results of FP32 grammar correction pipeline. Accuracy: 58.04%. Time: 61.03 sec.
Evaluation:   0%|          | 0/50 [00:00<?, ?it/s]
Evaluation results of INT8 grammar correction pipeline. Accuracy: 57.46%. Time: 42.38 sec.
Performance speedup: 1.440
Accuracy drop :0.59%.
Model footprint reduction: 3.989

Interactive demo

import gradio as gr
import time


def correct(text, quantized, progress=gr.Progress(track_tqdm=True)):
    grammar_corrector = grammar_corrector_pipe_int8 if quantized else grammar_corrector_pipe

    start_time = time.perf_counter()
    corrected_text = correct_text(text, grammar_checker_pipe, grammar_corrector)
    end_time = time.perf_counter()

    return corrected_text, f"{end_time - start_time:.2f}"


def create_demo_block(quantized: bool, show_model_type: bool):
    model_type = (" optimized" if quantized else " original") if show_model_type else ""
    with gr.Row():
        gr.Markdown(f"## Run{model_type} grammar correction pipeline")
    with gr.Row():
        with gr.Column():
            input_text = gr.Textbox(label="Text")
        with gr.Column():
            output_text = gr.Textbox(label="Correction")
            correction_time = gr.Textbox(label="Time (seconds)")
    with gr.Row():
        gr.Examples(examples=[default_text], inputs=[input_text])
    with gr.Row():
        button = gr.Button(f"Run{model_type}")
        button.click(correct, inputs=[input_text, gr.Number(quantized, visible=False)], outputs=[output_text, correction_time])


with gr.Blocks() as demo:
    gr.Markdown("# Interactive demo")
    quantization_is_present = grammar_corrector_pipe_int8 is not None
    create_demo_block(quantized=False, show_model_type=quantization_is_present)
    if quantization_is_present:
        create_demo_block(quantized=True, show_model_type=True)


# if you are launching remotely, specify server_name and server_port
# demo.launch(server_name='your server name', server_port='server port in int')
# Read more in the docs: https://gradio.app/docs/
try:
    demo.queue().launch(debug=False)
except Exception:
    demo.queue().launch(share=True, debug=False)
Running on local URL:  http://127.0.0.1:7860

To create a public link, set share=True in launch().