Vincentqyw
update: wrapper functions
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import os
import random
import numpy as np
import torch
from itertools import combinations
import cv2
import gradio as gr
from hloc import matchers, extractors
from hloc.utils.base_model import dynamic_load
from hloc import match_dense, match_features, extract_features
from .viz import draw_matches, fig2im, plot_images, plot_color_line_matches
device = "cuda" if torch.cuda.is_available() else "cpu"
def get_model(match_conf):
Model = dynamic_load(matchers, match_conf["model"]["name"])
model = Model(match_conf["model"]).eval().to(device)
return model
def get_feature_model(conf):
Model = dynamic_load(extractors, conf["model"]["name"])
model = Model(conf["model"]).eval().to(device)
return model
def gen_examples():
random.seed(1)
example_matchers = [
"disk+lightglue",
"loftr",
"disk",
"d2net",
"topicfm",
"superpoint+superglue",
"disk+dualsoftmax",
"lanet",
]
def gen_images_pairs(path: str, count: int = 5):
imgs_list = [
os.path.join(path, file)
for file in os.listdir(path)
if file.lower().endswith((".jpg", ".jpeg", ".png"))
]
pairs = list(combinations(imgs_list, 2))
selected = random.sample(range(len(pairs)), count)
return [pairs[i] for i in selected]
# image pair path
path = "datasets/sacre_coeur/mapping"
pairs = gen_images_pairs(path, len(example_matchers))
match_setting_threshold = 0.1
match_setting_max_features = 2000
detect_keypoints_threshold = 0.01
enable_ransac = False
ransac_method = "RANSAC"
ransac_reproj_threshold = 8
ransac_confidence = 0.999
ransac_max_iter = 10000
input_lists = []
for pair, mt in zip(pairs, example_matchers):
input_lists.append(
[
pair[0],
pair[1],
match_setting_threshold,
match_setting_max_features,
detect_keypoints_threshold,
mt,
enable_ransac,
ransac_method,
ransac_reproj_threshold,
ransac_confidence,
ransac_max_iter,
]
)
return input_lists
def filter_matches(
pred,
ransac_method="RANSAC",
ransac_reproj_threshold=8,
ransac_confidence=0.999,
ransac_max_iter=10000,
):
mkpts0 = None
mkpts1 = None
feature_type = None
if "keypoints0_orig" in pred.keys() and "keypoints1_orig" in pred.keys():
mkpts0 = pred["keypoints0_orig"]
mkpts1 = pred["keypoints1_orig"]
feature_type = "KEYPOINT"
elif (
"line_keypoints0_orig" in pred.keys()
and "line_keypoints1_orig" in pred.keys()
):
mkpts0 = pred["line_keypoints0_orig"]
mkpts1 = pred["line_keypoints1_orig"]
feature_type = "LINE"
else:
return pred
if mkpts0 is None or mkpts0 is None:
return pred
if ransac_method not in ransac_zoo.keys():
ransac_method = "RANSAC"
H, mask = cv2.findHomography(
mkpts0,
mkpts1,
method=ransac_zoo[ransac_method],
ransacReprojThreshold=ransac_reproj_threshold,
confidence=ransac_confidence,
maxIters=ransac_max_iter,
)
mask = np.array(mask.ravel().astype("bool"), dtype="bool")
if H is not None:
if feature_type == "KEYPOINT":
pred["keypoints0_orig"] = mkpts0[mask]
pred["keypoints1_orig"] = mkpts1[mask]
pred["mconf"] = pred["mconf"][mask]
elif feature_type == "LINE":
pred["line_keypoints0_orig"] = mkpts0[mask]
pred["line_keypoints1_orig"] = mkpts1[mask]
return pred
def compute_geom(
pred,
ransac_method="RANSAC",
ransac_reproj_threshold=8,
ransac_confidence=0.999,
ransac_max_iter=10000,
) -> dict:
mkpts0 = None
mkpts1 = None
if "keypoints0_orig" in pred.keys() and "keypoints1_orig" in pred.keys():
mkpts0 = pred["keypoints0_orig"]
mkpts1 = pred["keypoints1_orig"]
if (
"line_keypoints0_orig" in pred.keys()
and "line_keypoints1_orig" in pred.keys()
):
mkpts0 = pred["line_keypoints0_orig"]
mkpts1 = pred["line_keypoints1_orig"]
if mkpts0 is not None and mkpts1 is not None:
if len(mkpts0) < 8:
return {}
h1, w1, _ = pred["image0_orig"].shape
geo_info = {}
F, inliers = cv2.findFundamentalMat(
mkpts0,
mkpts1,
method=ransac_zoo[ransac_method],
ransacReprojThreshold=ransac_reproj_threshold,
confidence=ransac_confidence,
maxIters=ransac_max_iter,
)
geo_info["Fundamental"] = F.tolist()
H, _ = cv2.findHomography(
mkpts1,
mkpts0,
method=ransac_zoo[ransac_method],
ransacReprojThreshold=ransac_reproj_threshold,
confidence=ransac_confidence,
maxIters=ransac_max_iter,
)
geo_info["Homography"] = H.tolist()
_, H1, H2 = cv2.stereoRectifyUncalibrated(
mkpts0.reshape(-1, 2), mkpts1.reshape(-1, 2), F, imgSize=(w1, h1)
)
geo_info["H1"] = H1.tolist()
geo_info["H2"] = H2.tolist()
return geo_info
else:
return {}
def wrap_images(img0, img1, geo_info, geom_type):
h1, w1, _ = img0.shape
h2, w2, _ = img1.shape
result_matrix = None
if geo_info is not None and len(geo_info) != 0:
rectified_image0 = img0
rectified_image1 = None
H = np.array(geo_info["Homography"])
F = np.array(geo_info["Fundamental"])
title = []
if geom_type == "Homography":
rectified_image1 = cv2.warpPerspective(
img1, H, (img0.shape[1] + img1.shape[1], img0.shape[0])
)
result_matrix = H
title = ["Image 0", "Image 1 - warped"]
elif geom_type == "Fundamental":
H1, H2 = np.array(geo_info["H1"]), np.array(geo_info["H2"])
rectified_image0 = cv2.warpPerspective(img0, H1, (w1, h1))
rectified_image1 = cv2.warpPerspective(img1, H2, (w2, h2))
result_matrix = F
title = ["Image 0 - warped", "Image 1 - warped"]
else:
print("Error: Unknown geometry type")
fig = plot_images(
[rectified_image0.squeeze(), rectified_image1.squeeze()],
title,
dpi=300,
)
dictionary = {
"row1": result_matrix[0].tolist(),
"row2": result_matrix[1].tolist(),
"row3": result_matrix[2].tolist(),
}
return fig2im(fig), dictionary
else:
return None, None
def change_estimate_geom(input_image0, input_image1, matches_info, choice):
if (
matches_info is None
or len(matches_info) < 1
or "geom_info" not in matches_info.keys()
):
return None, None
geom_info = matches_info["geom_info"]
wrapped_images = None
if choice != "No":
wrapped_images, _ = wrap_images(
input_image0, input_image1, geom_info, choice
)
return wrapped_images, matches_info
else:
return None, None
def display_matches(pred: dict):
img0 = pred["image0_orig"]
img1 = pred["image1_orig"]
num_inliers = 0
if "keypoints0_orig" in pred.keys() and "keypoints1_orig" in pred.keys():
mkpts0 = pred["keypoints0_orig"]
mkpts1 = pred["keypoints1_orig"]
num_inliers = len(mkpts0)
if "mconf" in pred.keys():
mconf = pred["mconf"]
else:
mconf = np.ones(len(mkpts0))
fig_mkpts = draw_matches(
mkpts0,
mkpts1,
img0,
img1,
mconf,
dpi=300,
titles=[
"Image 0 - matched keypoints",
"Image 1 - matched keypoints",
],
)
fig = fig_mkpts
if "line0_orig" in pred.keys() and "line1_orig" in pred.keys():
# lines
mtlines0 = pred["line0_orig"]
mtlines1 = pred["line1_orig"]
num_inliers = len(mtlines0)
fig_lines = plot_images(
[img0.squeeze(), img1.squeeze()],
["Image 0 - matched lines", "Image 1 - matched lines"],
dpi=300,
)
fig_lines = plot_color_line_matches([mtlines0, mtlines1], lw=2)
fig_lines = fig2im(fig_lines)
# keypoints
mkpts0 = pred["line_keypoints0_orig"]
mkpts1 = pred["line_keypoints1_orig"]
if mkpts0 is not None and mkpts1 is not None:
num_inliers = len(mkpts0)
if "mconf" in pred.keys():
mconf = pred["mconf"]
else:
mconf = np.ones(len(mkpts0))
fig_mkpts = draw_matches(mkpts0, mkpts1, img0, img1, mconf, dpi=300)
fig_lines = cv2.resize(
fig_lines, (fig_mkpts.shape[1], fig_mkpts.shape[0])
)
fig = np.concatenate([fig_mkpts, fig_lines], axis=0)
else:
fig = fig_lines
return fig, num_inliers
def run_matching(
image0,
image1,
match_threshold,
extract_max_keypoints,
keypoint_threshold,
key,
enable_ransac=False,
ransac_method="RANSAC",
ransac_reproj_threshold=8,
ransac_confidence=0.999,
ransac_max_iter=10000,
choice_estimate_geom="Homography",
):
# image0 and image1 is RGB mode
if image0 is None or image1 is None:
raise gr.Error("Error: No images found! Please upload two images.")
model = matcher_zoo[key]
match_conf = model["config"]
# update match config
match_conf["model"]["match_threshold"] = match_threshold
match_conf["model"]["max_keypoints"] = extract_max_keypoints
matcher = get_model(match_conf)
if model["dense"]:
pred = match_dense.match_images(
matcher, image0, image1, match_conf["preprocessing"], device=device
)
del matcher
extract_conf = None
else:
extract_conf = model["config_feature"]
# update extract config
extract_conf["model"]["max_keypoints"] = extract_max_keypoints
extract_conf["model"]["keypoint_threshold"] = keypoint_threshold
extractor = get_feature_model(extract_conf)
pred0 = extract_features.extract(
extractor, image0, extract_conf["preprocessing"]
)
pred1 = extract_features.extract(
extractor, image1, extract_conf["preprocessing"]
)
pred = match_features.match_images(matcher, pred0, pred1)
del extractor
if enable_ransac:
filter_matches(
pred,
ransac_method=ransac_method,
ransac_reproj_threshold=ransac_reproj_threshold,
ransac_confidence=ransac_confidence,
ransac_max_iter=ransac_max_iter,
)
fig, num_inliers = display_matches(pred)
geom_info = compute_geom(pred)
output_wrapped, _ = change_estimate_geom(
pred["image0_orig"],
pred["image1_orig"],
{"geom_info": geom_info},
choice_estimate_geom,
)
del pred
return (
fig,
{"matches number": num_inliers},
{
"match_conf": match_conf,
"extractor_conf": extract_conf,
},
{
"geom_info": geom_info,
},
output_wrapped,
# geometry_result,
)
# @ref: https://docs.opencv.org/4.x/d0/d74/md__build_4_x-contrib_docs-lin64_opencv_doc_tutorials_calib3d_usac.html
# AND: https://opencv.org/blog/2021/06/09/evaluating-opencvs-new-ransacs
ransac_zoo = {
"RANSAC": cv2.RANSAC,
"USAC_MAGSAC": cv2.USAC_MAGSAC,
"USAC_DEFAULT": cv2.USAC_DEFAULT,
"USAC_FM_8PTS": cv2.USAC_FM_8PTS,
"USAC_PROSAC": cv2.USAC_PROSAC,
"USAC_FAST": cv2.USAC_FAST,
"USAC_ACCURATE": cv2.USAC_ACCURATE,
"USAC_PARALLEL": cv2.USAC_PARALLEL,
}
# Matchers collections
matcher_zoo = {
"gluestick": {"config": match_dense.confs["gluestick"], "dense": True},
"sold2": {"config": match_dense.confs["sold2"], "dense": True},
# 'dedode-sparse': {
# 'config': match_dense.confs['dedode_sparse'],
# 'dense': True # dense mode, we need 2 images
# },
"loftr": {"config": match_dense.confs["loftr"], "dense": True},
"topicfm": {"config": match_dense.confs["topicfm"], "dense": True},
"aspanformer": {"config": match_dense.confs["aspanformer"], "dense": True},
"dedode": {
"config": match_features.confs["Dual-Softmax"],
"config_feature": extract_features.confs["dedode"],
"dense": False,
},
"superpoint+superglue": {
"config": match_features.confs["superglue"],
"config_feature": extract_features.confs["superpoint_max"],
"dense": False,
},
"superpoint+lightglue": {
"config": match_features.confs["superpoint-lightglue"],
"config_feature": extract_features.confs["superpoint_max"],
"dense": False,
},
"disk": {
"config": match_features.confs["NN-mutual"],
"config_feature": extract_features.confs["disk"],
"dense": False,
},
"disk+dualsoftmax": {
"config": match_features.confs["Dual-Softmax"],
"config_feature": extract_features.confs["disk"],
"dense": False,
},
"superpoint+dualsoftmax": {
"config": match_features.confs["Dual-Softmax"],
"config_feature": extract_features.confs["superpoint_max"],
"dense": False,
},
"disk+lightglue": {
"config": match_features.confs["disk-lightglue"],
"config_feature": extract_features.confs["disk"],
"dense": False,
},
"superpoint+mnn": {
"config": match_features.confs["NN-mutual"],
"config_feature": extract_features.confs["superpoint_max"],
"dense": False,
},
"sift+sgmnet": {
"config": match_features.confs["sgmnet"],
"config_feature": extract_features.confs["sift"],
"dense": False,
},
"sosnet": {
"config": match_features.confs["NN-mutual"],
"config_feature": extract_features.confs["sosnet"],
"dense": False,
},
"hardnet": {
"config": match_features.confs["NN-mutual"],
"config_feature": extract_features.confs["hardnet"],
"dense": False,
},
"d2net": {
"config": match_features.confs["NN-mutual"],
"config_feature": extract_features.confs["d2net-ss"],
"dense": False,
},
# "d2net-ms": {
# "config": match_features.confs["NN-mutual"],
# "config_feature": extract_features.confs["d2net-ms"],
# "dense": False,
# },
"alike": {
"config": match_features.confs["NN-mutual"],
"config_feature": extract_features.confs["alike"],
"dense": False,
},
"lanet": {
"config": match_features.confs["NN-mutual"],
"config_feature": extract_features.confs["lanet"],
"dense": False,
},
"r2d2": {
"config": match_features.confs["NN-mutual"],
"config_feature": extract_features.confs["r2d2"],
"dense": False,
},
"darkfeat": {
"config": match_features.confs["NN-mutual"],
"config_feature": extract_features.confs["darkfeat"],
"dense": False,
},
"sift": {
"config": match_features.confs["NN-mutual"],
"config_feature": extract_features.confs["sift"],
"dense": False,
},
# "roma": {"config": match_dense.confs["roma"], "dense": True},
# "DKMv3": {"config": match_dense.confs["dkm"], "dense": True},
}