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from typing import List, Union

import datasets
import numpy as np
import torch
import torchvision.transforms as T
from PIL import Image
from tqdm.auto import tqdm
from transformers import AutoFeatureExtractor, AutoModel

seed = 42
hash_size = 8
hidden_dim = 768  # ViT-base
np.random.seed(seed)


# Device.
device = "cuda" if torch.cuda.is_available() else "cpu"

# Load model for computing embeddings..
model_ckpt = "nateraw/vit-base-beans"
extractor = AutoFeatureExtractor.from_pretrained(model_ckpt)

# Data transformation chain.
transformation_chain = T.Compose(
    [
        # We first resize the input image to 256x256 and then we take center crop.
        T.Resize(int((256 / 224) * extractor.size["height"])),
        T.CenterCrop(extractor.size["height"]),
        T.ToTensor(),
        T.Normalize(mean=extractor.image_mean, std=extractor.image_std),
    ]
)


# Define random vectors to project with.
random_vectors = np.random.randn(hash_size, hidden_dim).T


def hash_func(embedding, random_vectors=random_vectors):
    """Randomly projects the embeddings and then computes bit-wise hashes."""
    if not isinstance(embedding, np.ndarray):
        embedding = np.array(embedding)
    if len(embedding.shape) < 2:
        embedding = np.expand_dims(embedding, 0)

    # Random projection.
    bools = np.dot(embedding, random_vectors) > 0
    return [bool2int(bool_vec) for bool_vec in bools]


def bool2int(x):
    y = 0
    for i, j in enumerate(x):
        if j:
            y += 1 << i
    return y


def compute_hash(model: Union[torch.nn.Module, str]):
    """Computes hash on a given dataset."""
    device = model.device

    def pp(example_batch):
        # Prepare the input images for the model.
        image_batch = example_batch["image"]
        image_batch_transformed = torch.stack(
            [transformation_chain(image) for image in image_batch]
        )
        new_batch = {"pixel_values": image_batch_transformed.to(device)}

        # Compute embeddings and pool them i.e., take the representations from the [CLS]
        # token.
        with torch.no_grad():
            embeddings = model(**new_batch).last_hidden_state[:, 0].cpu().numpy()

        # Compute hashes for the batch of images.
        hashes = [hash_func(embeddings[i]) for i in range(len(embeddings))]
        example_batch["hashes"] = hashes
        return example_batch

    return pp


class Table:
    def __init__(self, hash_size: int):
        self.table = {}
        self.hash_size = hash_size

    def add(self, id: int, hashes: List[int], label: int):
        # Create a unique indentifier.
        entry = {"id_label": str(id) + "_" + str(label)}

        # Add the hash values to the current table.
        for h in hashes:
            if h in self.table:
                self.table[h].append(entry)
            else:
                self.table[h] = [entry]

    def query(self, hashes: List[int]):
        results = []

        # Loop over the query hashes and determine if they exist in
        # the current table.
        for h in hashes:
            if h in self.table:
                results.extend(self.table[h])
        return results


class LSH:
    def __init__(self, hash_size, num_tables):
        self.num_tables = num_tables
        self.tables = []
        for i in range(self.num_tables):
            self.tables.append(Table(hash_size))

    def add(self, id: int, hash: List[int], label: int):
        for table in self.tables:
            table.add(id, hash, label)

    def query(self, hashes: List[int]):
        results = []
        for table in self.tables:
            results.extend(table.query(hashes))
        return results


class BuildLSHTable:
    def __init__(
        self,
        model: Union[torch.nn.Module, None],
        batch_size: int = 48,
        hash_size: int = hash_size,
        dim: int = hidden_dim,
        num_tables: int = 10,
    ):
        self.hash_size = hash_size
        self.dim = dim
        self.num_tables = num_tables
        self.lsh = LSH(self.hash_size, self.num_tables)

        self.batch_size = batch_size
        self.hash_fn = compute_hash(model.to(device))

    def build(self, ds: datasets.DatasetDict):
        dataset_hashed = ds.map(self.hash_fn, batched=True, batch_size=self.batch_size)

        for id in tqdm(range(len(dataset_hashed))):
            hash, label = dataset_hashed[id]["hashes"], dataset_hashed[id]["labels"]
            self.lsh.add(id, hash, label)

    def query(self, image, verbose=True):
        if isinstance(image, str):
            image = Image.open(image).convert("RGB")

        # Compute the hashes of the query image and fetch the results.
        example_batch = dict(image=[image])
        hashes = self.hash_fn(example_batch)["hashes"][0]

        results = self.lsh.query(hashes)
        if verbose:
            print("Matches:", len(results))

        # Calculate Jaccard index to quantify the similarity.
        counts = {}
        for r in results:
            if r["id_label"] in counts:
                counts[r["id_label"]] += 1
            else:
                counts[r["id_label"]] = 1
        for k in counts:
            counts[k] = float(counts[k]) / self.dim
        return counts