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| import streamlit as st | |
| from text2image import get_model, get_tokenizer, get_image_transform | |
| from utils import text_encoder | |
| from torchvision import transforms | |
| from PIL import Image | |
| from jax import numpy as jnp | |
| import pandas as pd | |
| import numpy as np | |
| import requests | |
| import psutil | |
| import time | |
| import jax | |
| import gc | |
| preprocess = transforms.Compose([ | |
| transforms.ToTensor(), | |
| transforms.Normalize((0.48145466, 0.4578275, 0.40821073), (0.26862954, 0.26130258, 0.27577711)), | |
| ]) | |
| def pad_to_square(image, size=224): | |
| ratio = float(size) / max(image.size) | |
| new_size = tuple([int(x * ratio) for x in image.size]) | |
| image = image.resize(new_size, Image.ANTIALIAS) | |
| new_image = Image.new("RGB", size=(size, size), color=(128, 128, 128)) | |
| new_image.paste(image, ((size - new_size[0]) // 2, (size - new_size[1]) // 2)) | |
| return new_image | |
| def image_encoder(image, model): | |
| image = np.transpose(image, (0, 2, 3, 1)) | |
| features = model.get_image_features(image) | |
| features /= jnp.linalg.norm(features, keepdims=True) | |
| return features | |
| def gen_image_batch(image_url, image_size=224, pixel_size=10): | |
| n_pixels = image_size // pixel_size + 1 | |
| image_batch = [] | |
| masks = [] | |
| image_raw = requests.get(image_url, stream=True).raw | |
| image = Image.open(image_raw).convert("RGB") | |
| image = pad_to_square(image, size=image_size) | |
| gray = np.ones_like(image) * 128 | |
| mask = np.ones_like(image) | |
| image_batch.append(image) | |
| masks.append(mask) | |
| for i in range(0, n_pixels): | |
| for j in range(i+1, n_pixels): | |
| m = mask.copy() | |
| m[:min(i*pixel_size, image_size) + 1, :] = 0 | |
| m[min(j*pixel_size, image_size) + 1:, :] = 0 | |
| neg_m = 1 - m | |
| image_batch.append(image * m + gray * neg_m) | |
| masks.append(m) | |
| for i in range(0, n_pixels+1): | |
| for j in range(i+1, n_pixels+1): | |
| m = mask.copy() | |
| m[:, :min(i*pixel_size + 1, image_size)] = 0 | |
| m[:, min(j*pixel_size + 1, image_size):] = 0 | |
| neg_m = 1 - m | |
| image_batch.append(image * m + gray * neg_m) | |
| masks.append(m) | |
| return image_batch, masks | |
| def get_heatmap(image_url, text, pixel_size=10, iterations=3): | |
| tokenizer = get_tokenizer() | |
| model = get_model() | |
| image_size = model.config.vision_config.image_size | |
| text_embedding = text_encoder(text, model, tokenizer) | |
| images, masks = gen_image_batch(image_url, image_size=image_size, pixel_size=pixel_size) | |
| input_image = images[0].copy() | |
| images = np.stack([preprocess(image) for image in images], axis=0) | |
| image_embeddings = jnp.asarray(image_encoder(images, model)) | |
| sims = [] | |
| scores = [] | |
| mask_val = jnp.zeros_like(masks[0]) | |
| for e, m in zip(image_embeddings, masks): | |
| sim = jnp.matmul(e, text_embedding.T) | |
| sims.append(sim) | |
| if len(sims) > 1: | |
| scores.append(sim * m) | |
| mask_val += 1 - m | |
| score = jnp.mean(jnp.clip(jnp.array(scores) - sims[0], 0, jnp.inf), axis=0) | |
| for i in range(iterations): | |
| score = jnp.clip(score - jnp.mean(score), 0, jnp.inf) | |
| score = (score - jnp.min(score)) / (jnp.max(score) - jnp.min(score)) | |
| return np.asarray(score), input_image | |
| def app(): | |
| st.title("Zero-Shot Localization") | |
| st.markdown( | |
| """ | |
| ### π Ciao! | |
| Here you can find an example for zero shot localization that will show you where in an image the model sees an object. | |
| The location of the object is computed by masking different areas of the image and looking at | |
| how the similarity to the image description changes. If you want to have a look at the implementation in details | |
| you can find it in [this Colab](https://colab.research.google.com/drive/10neENr1DEAFq_GzsLqBDo0gZ50hOhkOr?usp=sharing). | |
| On the two parameters: the pixel size defines the resolution of the localization map. A pixel size of 15 means | |
| that 15 pixels in the original image will form 1 pixel in the heatmap. The refinement | |
| iterations are just a cheap operation to reduce background noise. Too few iterations will leave a lot of noise. | |
| Too many will shrink the heatmap too much. | |
| π€ Italian mode on! π€ | |
| For example, try typing "gatto" (cat) or "cane" (dog) in the space for label and click "locate"! | |
| """ | |
| ) | |
| image_url = st.text_input( | |
| "You can input the URL of an image here...", | |
| value="https://www.tuttosuigatti.it/files/styles/full_width/public/images/featured/205/cani-e-gatti.jpg?itok=WAAiTGS6", | |
| ) | |
| MAX_ITER = 1 | |
| col1, col2 = st.beta_columns([3, 1]) | |
| with col2: | |
| pixel_size = st.selectbox( | |
| "Pixel Size", options=range(10, 21, 5), index=0 | |
| ) | |
| iterations = st.selectbox( | |
| "Refinement Steps", options=range(3, 30, 3), index=0 | |
| ) | |
| compute = st.button("LOCATE") | |
| with col1: | |
| caption = st.text_input(f"Insert label...") | |
| if compute: | |
| with st.spinner('Waiting for resources...'): | |
| sleep_time = 5 | |
| print('CPU_load', psutil.cpu_percent()) | |
| while psutil.cpu_percent() > 60: | |
| time.sleep(sleep_time) | |
| if not caption or not image_url: | |
| st.error("Please choose one image and at least one label") | |
| else: | |
| with st.spinner("Computing... This might take up to a few minutes depending on the current load π \n" | |
| "[Colab Link](https://colab.research.google.com/drive/10neENr1DEAFq_GzsLqBDo0gZ50hOhkOr?usp=sharing)"): | |
| heatmap, image = get_heatmap(image_url, caption, pixel_size, iterations) | |
| with col1: | |
| st.image(image, use_column_width=True) | |
| st.image(heatmap, use_column_width=True) | |
| st.image(np.asarray(image) / 255.0 * heatmap, use_column_width=True) | |
| gc.collect() | |
| elif image_url: | |
| image_raw = requests.get(image_url, stream=True, ).raw | |
| image = Image.open(image_raw).convert("RGB") | |
| with col1: | |
| st.image(image) | |