| import numpy as np |
| import pandas as pd |
|
|
| from PIL import Image |
| from tqdm import tqdm |
| from scipy.sparse import csr_matrix |
| from typing import Mapping, List, Tuple, Union |
| from transformers.pipelines import Pipeline, pipeline |
|
|
| from bertopic.representation._mmr import mmr |
| from bertopic.representation._base import BaseRepresentation |
|
|
|
|
| class VisualRepresentation(BaseRepresentation): |
| """ From a collection of representative documents, extract |
| images to represent topics. These topics are represented by a |
| collage of images. |
| |
| Arguments: |
| nr_repr_images: Number of representative images to extract |
| nr_samples: The number of candidate documents to extract per cluster. |
| image_height: The height of the resulting collage |
| image_square: Whether to resize each image in the collage |
| to a square. This can be visually more appealing |
| if all input images are all almost squares. |
| image_to_text_model: The model to caption images. |
| batch_size: The number of images to pass to the |
| `image_to_text_model`. |
| |
| Usage: |
| |
| ```python |
| from bertopic.representation import VisualRepresentation |
| from bertopic import BERTopic |
| |
| # The visual representation is typically not a core representation |
| # and is advised to pass to BERTopic as an additional aspect. |
| # Aspects can be labeled with dictionaries as shown below: |
| representation_model = { |
| "Visual_Aspect": VisualRepresentation() |
| } |
| |
| # Use the representation model in BERTopic as a separate aspect |
| topic_model = BERTopic(representation_model=representation_model) |
| ``` |
| """ |
| def __init__(self, |
| nr_repr_images: int = 9, |
| nr_samples: int = 500, |
| image_height: Tuple[int, int] = 600, |
| image_squares: bool = False, |
| image_to_text_model: Union[str, Pipeline] = None, |
| batch_size: int = 32): |
| self.nr_repr_images = nr_repr_images |
| self.nr_samples = nr_samples |
| self.image_height = image_height |
| self.image_squares = image_squares |
|
|
| |
| if isinstance(image_to_text_model, Pipeline): |
| self.image_to_text_model = image_to_text_model |
| elif isinstance(image_to_text_model, str): |
| self.image_to_text_model = pipeline("image-to-text", model=image_to_text_model) |
| elif image_to_text_model is None: |
| self.image_to_text_model = None |
| else: |
| raise ValueError("Please select a correct transformers pipeline. For example:" |
| "pipeline('image-to-text', model='nlpconnect/vit-gpt2-image-captioning')") |
| self.batch_size = batch_size |
|
|
| def extract_topics(self, |
| topic_model, |
| documents: pd.DataFrame, |
| c_tf_idf: csr_matrix, |
| topics: Mapping[str, List[Tuple[str, float]]] |
| ) -> Mapping[str, List[Tuple[str, float]]]: |
| """ Extract topics |
| |
| Arguments: |
| topic_model: A BERTopic model |
| documents: All input documents |
| c_tf_idf: The topic c-TF-IDF representation |
| topics: The candidate topics as calculated with c-TF-IDF |
| |
| Returns: |
| representative_images: Representative images per topic |
| """ |
| |
| images = documents["Image"].values.tolist() |
| (_, _, _, |
| repr_docs_ids) = topic_model._extract_representative_docs(c_tf_idf, |
| documents, |
| topics, |
| nr_samples=self.nr_samples, |
| nr_repr_docs=self.nr_repr_images) |
| unique_topics = sorted(list(topics.keys())) |
|
|
| |
| representative_images = {} |
| for topic in tqdm(unique_topics): |
| |
| |
| sliced_examplars = repr_docs_ids[topic+topic_model._outliers] |
| sliced_examplars = [sliced_examplars[i:i + 3] for i in |
| range(0, len(sliced_examplars), 3)] |
| images_to_combine = [ |
| [Image.open(images[index]) if isinstance(images[index], str) |
| else images[index] for index in sub_indices] |
| for sub_indices in sliced_examplars |
| ] |
|
|
| |
| representative_image = get_concat_tile_resize(images_to_combine, |
| self.image_height, |
| self.image_squares) |
| representative_images[topic] = representative_image |
|
|
| |
| if isinstance(images[0], str): |
| for image_list in images_to_combine: |
| for image in image_list: |
| image.close() |
| |
| return representative_images |
| |
| def _convert_image_to_text(self, |
| images: List[str], |
| verbose: bool = False) -> List[str]: |
| """ Convert a list of images to captions. |
| |
| Arguments: |
| images: A list of images or words to be converted to text. |
| verbose: Controls the verbosity of the process |
| |
| Returns: |
| List of captions |
| """ |
| |
| if self.batch_size is not None: |
| documents = [] |
| for batch in tqdm(self._chunks(images), disable=not verbose): |
| outputs = self.image_to_text_model(batch) |
| captions = [output[0]["generated_text"] for output in outputs] |
| documents.extend(captions) |
|
|
| |
| else: |
| outputs = self.image_to_text_model(images) |
| documents = [output[0]["generated_text"] for output in outputs] |
|
|
| return documents |
| |
| def image_to_text(self, documents: pd.DataFrame, embeddings: np.ndarray) -> pd.DataFrame: |
| """ Convert images to text """ |
| |
| topics = documents.Topic.values.tolist() |
| images = documents.Image.values.tolist() |
| df = pd.DataFrame(np.hstack([np.array(topics).reshape(-1, 1), embeddings])) |
| image_topic_embeddings = df.groupby(0).mean().values |
| |
| |
| image_centroids = {} |
| unique_topics = sorted(list(set(topics))) |
| for topic, topic_embedding in zip(unique_topics, image_topic_embeddings): |
| indices = np.array([index for index, t in enumerate(topics) if t == topic]) |
| top_n = min([self.nr_repr_images, len(indices)]) |
| indices = mmr(topic_embedding.reshape(1, -1), embeddings[indices], indices, top_n=top_n, diversity=0.1) |
| image_centroids[topic] = indices |
| |
| |
| documents = pd.DataFrame(columns=["Document", "ID", "Topic", "Image"]) |
| current_id = 0 |
| for topic, image_ids in tqdm(image_centroids.items()): |
| selected_images = [Image.open(images[index]) if isinstance(images[index], str) else images[index] for index in image_ids] |
| text = self._convert_image_to_text(selected_images) |
| |
| for doc, image_id in zip(text, image_ids): |
| documents.loc[len(documents), :] = [doc, current_id, topic, images[image_id]] |
| current_id += 1 |
| |
| |
| if isinstance(images[image_ids[0]], str): |
| for image in selected_images: |
| image.close() |
|
|
| return documents |
|
|
| def _chunks(self, images): |
| for i in range(0, len(images), self.batch_size): |
| yield images[i:i + self.batch_size] |
|
|
|
|
| def get_concat_h_multi_resize(im_list): |
| """ |
| Code adapted from: https://note.nkmk.me/en/python-pillow-concat-images/ |
| """ |
| min_height = min(im.height for im in im_list) |
| min_height = max(im.height for im in im_list) |
| im_list_resize = [] |
| for im in im_list: |
| im.resize((int(im.width * min_height / im.height), min_height), resample=0) |
| im_list_resize.append(im) |
|
|
| total_width = sum(im.width for im in im_list_resize) |
| dst = Image.new('RGB', (total_width, min_height), (255, 255, 255)) |
| pos_x = 0 |
| for im in im_list_resize: |
| dst.paste(im, (pos_x, 0)) |
| pos_x += im.width |
| return dst |
|
|
|
|
| def get_concat_v_multi_resize(im_list): |
| """ |
| Code adapted from: https://note.nkmk.me/en/python-pillow-concat-images/ |
| """ |
| min_width = min(im.width for im in im_list) |
| min_width = max(im.width for im in im_list) |
| im_list_resize = [im.resize((min_width, int(im.height * min_width / im.width)), resample=0) |
| for im in im_list] |
| total_height = sum(im.height for im in im_list_resize) |
| dst = Image.new('RGB', (min_width, total_height), (255, 255, 255)) |
| pos_y = 0 |
| for im in im_list_resize: |
| dst.paste(im, (0, pos_y)) |
| pos_y += im.height |
| return dst |
|
|
|
|
| def get_concat_tile_resize(im_list_2d, image_height=600, image_squares=False): |
| """ |
| Code adapted from: https://note.nkmk.me/en/python-pillow-concat-images/ |
| """ |
| images = [[image.copy() for image in images] for images in im_list_2d] |
| |
| |
| if image_squares: |
| width = int(image_height / 3) |
| height = int(image_height / 3) |
| images = [[image.resize((width, height)) for image in images] for images in im_list_2d] |
| |
| |
| else: |
| min_width = min([min([img.width for img in imgs]) for imgs in im_list_2d]) |
| min_height = min([min([img.height for img in imgs]) for imgs in im_list_2d]) |
| for i, imgs in enumerate(images): |
| for j, img in enumerate(imgs): |
| if img.height > img.width: |
| images[i][j] = img.resize((int(img.width * min_height / img.height), min_height), resample=0) |
| elif img.width > img.height: |
| images[i][j] = img.resize((min_width, int(img.height * min_width / img.width)), resample=0) |
| else: |
| images[i][j] = img.resize((min_width, min_width)) |
|
|
| |
| images = [get_concat_h_multi_resize(im_list_h) for im_list_h in images] |
| img = get_concat_v_multi_resize(images) |
| height_percentage = (image_height/float(img.size[1])) |
| adjusted_width = int((float(img.size[0])*float(height_percentage))) |
| img = img.resize((adjusted_width, image_height), Image.Resampling.LANCZOS) |
| |
| return img |
|
|