import matplotlib.pyplot as plt import nmslib import numpy as np import os import streamlit as st from transformers import CLIPProcessor, FlaxCLIPModel BASELINE_MODEL = "openai/clip-vit-base-patch32" # MODEL_PATH = "/home/shared/models/clip-rsicd/bs128x8-lr5e-6-adam/ckpt-1" MODEL_PATH = "flax-community/clip-rsicd" # IMAGE_VECTOR_FILE = "/home/shared/data/vectors/test-baseline.tsv" # IMAGE_VECTOR_FILE = "/home/shared/data/vectors/test-bs128x8-lr5e-6-adam-ckpt-1.tsv" IMAGE_VECTOR_FILE = "./vectors/test-bs128x8-lr5e-6-adam-ckpt-1.tsv" # IMAGES_DIR = "/home/shared/data/rsicd_images" IMAGES_DIR = "./images" @st.cache(allow_output_mutation=True) def load_index(): filenames, image_vecs = [], [] fvec = open(IMAGE_VECTOR_FILE, "r") for line in fvec: cols = line.strip().split('\t') filename = cols[0] image_vec = np.array([float(x) for x in cols[1].split(',')]) filenames.append(filename) image_vecs.append(image_vec) V = np.array(image_vecs) index = nmslib.init(method='hnsw', space='cosinesimil') index.addDataPointBatch(V) index.createIndex({'post': 2}, print_progress=True) return filenames, index @st.cache(allow_output_mutation=True) def load_model(): model = FlaxCLIPModel.from_pretrained(MODEL_PATH) processor = CLIPProcessor.from_pretrained(BASELINE_MODEL) return model, processor def app(): filenames, index = load_index() model, processor = load_model() st.title("Text to Image Retrieval") st.markdown(""" The CLIP model from OpenAI is trained in a self-supervised manner using contrastive learning to project images and caption text onto a common embedding space. We have fine-tuned the model using the RSICD dataset (10k images and ~50k captions from the remote sensing domain). This demo shows the image to text retrieval capabilities of this model, i.e., given a text query, we use our fine-tuned CLIP model to project the text query to the image/caption embedding space and search for nearby images (by cosine similarity) in this space. Our fine-tuned CLIP model was previously used to generate image vectors for our demo, and NMSLib was used for fast vector access. Some suggested queries to start you off with -- "ships", "school house", "military installations", "mountains", "beaches", "airports", "lakes", etc. """) query = st.text_input("Text Query:") if st.button("Query"): inputs = processor(text=[query], images=None, return_tensors="jax", padding=True) query_vec = model.get_text_features(**inputs) query_vec = np.asarray(query_vec) ids, distances = index.knnQuery(query_vec, k=10) result_filenames = [filenames[id] for id in ids] images, captions = [], [] for result_filename, score in zip(result_filenames, distances): images.append( plt.imread(os.path.join(IMAGES_DIR, result_filename))) captions.append("{:s} (score: {:.3f})".format(result_filename, 1.0 - score)) st.image(images[0:3], caption=captions[0:3]) st.image(images[3:6], caption=captions[3:6]) st.image(images[6:9], caption=captions[6:9]) st.image(images[9:], caption=captions[9:])