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import cv2
import os
from tqdm import tqdm
import torch
import numpy as np
from extract import extract_method

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

methods = [
    "d2",
    "lfnet",
    "superpoint",
    "r2d2",
    "aslfeat",
    "disk",
    "alike-n",
    "alike-l",
    "alike-n-ms",
    "alike-l-ms",
]
names = [
    "D2-Net(MS)",
    "LF-Net(MS)",
    "SuperPoint",
    "R2D2(MS)",
    "ASLFeat(MS)",
    "DISK",
    "ALike-N",
    "ALike-L",
    "ALike-N(MS)",
    "ALike-L(MS)",
]

top_k = None
n_i = 52
n_v = 56
cache_dir = "hseq/cache"
dataset_path = "hseq/hpatches-sequences-release"


def generate_read_function(method, extension="ppm"):
    def read_function(seq_name, im_idx):
        aux = np.load(
            os.path.join(
                dataset_path, seq_name, "%d.%s.%s" % (im_idx, extension, method)
            )
        )
        if top_k is None:
            return aux["keypoints"], aux["descriptors"]
        else:
            assert "scores" in aux
            ids = np.argsort(aux["scores"])[-top_k:]
            return aux["keypoints"][ids, :], aux["descriptors"][ids, :]

    return read_function


def mnn_matcher(descriptors_a, descriptors_b):
    device = descriptors_a.device
    sim = descriptors_a @ descriptors_b.t()
    nn12 = torch.max(sim, dim=1)[1]
    nn21 = torch.max(sim, dim=0)[1]
    ids1 = torch.arange(0, sim.shape[0], device=device)
    mask = ids1 == nn21[nn12]
    matches = torch.stack([ids1[mask], nn12[mask]])
    return matches.t().data.cpu().numpy()


def homo_trans(coord, H):
    kpt_num = coord.shape[0]
    homo_coord = np.concatenate((coord, np.ones((kpt_num, 1))), axis=-1)
    proj_coord = np.matmul(H, homo_coord.T).T
    proj_coord = proj_coord / proj_coord[:, 2][..., None]
    proj_coord = proj_coord[:, 0:2]
    return proj_coord


def benchmark_features(read_feats):
    lim = [1, 5]
    rng = np.arange(lim[0], lim[1] + 1)

    seq_names = sorted(os.listdir(dataset_path))

    n_feats = []
    n_matches = []
    seq_type = []
    i_err = {thr: 0 for thr in rng}
    v_err = {thr: 0 for thr in rng}

    i_err_homo = {thr: 0 for thr in rng}
    v_err_homo = {thr: 0 for thr in rng}

    for seq_idx, seq_name in tqdm(enumerate(seq_names), total=len(seq_names)):
        keypoints_a, descriptors_a = read_feats(seq_name, 1)
        n_feats.append(keypoints_a.shape[0])

        # =========== compute homography
        ref_img = cv2.imread(os.path.join(dataset_path, seq_name, "1.ppm"))
        ref_img_shape = ref_img.shape

        for im_idx in range(2, 7):
            keypoints_b, descriptors_b = read_feats(seq_name, im_idx)
            n_feats.append(keypoints_b.shape[0])

            matches = mnn_matcher(
                torch.from_numpy(descriptors_a).to(device=device),
                torch.from_numpy(descriptors_b).to(device=device),
            )

            homography = np.loadtxt(
                os.path.join(dataset_path, seq_name, "H_1_" + str(im_idx))
            )

            pos_a = keypoints_a[matches[:, 0], :2]
            pos_a_h = np.concatenate([pos_a, np.ones([matches.shape[0], 1])], axis=1)
            pos_b_proj_h = np.transpose(np.dot(homography, np.transpose(pos_a_h)))
            pos_b_proj = pos_b_proj_h[:, :2] / pos_b_proj_h[:, 2:]

            pos_b = keypoints_b[matches[:, 1], :2]

            dist = np.sqrt(np.sum((pos_b - pos_b_proj) ** 2, axis=1))

            n_matches.append(matches.shape[0])
            seq_type.append(seq_name[0])

            if dist.shape[0] == 0:
                dist = np.array([float("inf")])

            for thr in rng:
                if seq_name[0] == "i":
                    i_err[thr] += np.mean(dist <= thr)
                else:
                    v_err[thr] += np.mean(dist <= thr)

            # =========== compute homography
            gt_homo = homography
            pred_homo, _ = cv2.findHomography(
                keypoints_a[matches[:, 0], :2],
                keypoints_b[matches[:, 1], :2],
                cv2.RANSAC,
            )
            if pred_homo is None:
                homo_dist = np.array([float("inf")])
            else:
                corners = np.array(
                    [
                        [0, 0],
                        [ref_img_shape[1] - 1, 0],
                        [0, ref_img_shape[0] - 1],
                        [ref_img_shape[1] - 1, ref_img_shape[0] - 1],
                    ]
                )
                real_warped_corners = homo_trans(corners, gt_homo)
                warped_corners = homo_trans(corners, pred_homo)
                homo_dist = np.mean(
                    np.linalg.norm(real_warped_corners - warped_corners, axis=1)
                )

            for thr in rng:
                if seq_name[0] == "i":
                    i_err_homo[thr] += np.mean(homo_dist <= thr)
                else:
                    v_err_homo[thr] += np.mean(homo_dist <= thr)

    seq_type = np.array(seq_type)
    n_feats = np.array(n_feats)
    n_matches = np.array(n_matches)

    return i_err, v_err, i_err_homo, v_err_homo, [seq_type, n_feats, n_matches]


if __name__ == "__main__":
    errors = {}
    for method in methods:
        output_file = os.path.join(cache_dir, method + ".npy")
        read_function = generate_read_function(method)
        if os.path.exists(output_file):
            errors[method] = np.load(output_file, allow_pickle=True)
        else:
            extract_method(method)
            errors[method] = benchmark_features(read_function)
            np.save(output_file, errors[method])

    for name, method in zip(names, methods):
        i_err, v_err, i_err_hom, v_err_hom, _ = errors[method]

        print(f"====={name}=====")
        print(f"MMA@1 MMA@2 MMA@3 MHA@1 MHA@2 MHA@3: ", end="")
        for thr in range(1, 4):
            err = (i_err[thr] + v_err[thr]) / ((n_i + n_v) * 5)
            print(f"{err * 100:.2f}%", end=" ")
        for thr in range(1, 4):
            err_hom = (i_err_hom[thr] + v_err_hom[thr]) / ((n_i + n_v) * 5)
            print(f"{err_hom * 100:.2f}%", end=" ")
        print("")