wwen1997's picture
Upload 13 files
7615afe verified
Raw
History Blame Contribute Delete
8.31 kB
from scipy.interpolate import interp1d, PchipInterpolator
import numpy as np
from PIL import Image
import cv2
import torch
def sift_match(
img1, img2,
thr=0.5,
topk=5, method="max_dist",
output_path="sift_matches.png",
):
assert method in ["max_dist", "random", "max_score", "max_score_even"]
# img1 and img2 are PIL images
# small threshold means less points
# 1. to cv2 grayscale image
img1_rgb = np.array(img1).copy()
img2_rgb = np.array(img2).copy()
img1 = cv2.cvtColor(np.array(img1), cv2.COLOR_RGB2BGR)
img1 = cv2.cvtColor(img1, cv2.COLOR_BGR2GRAY)
img2 = cv2.cvtColor(np.array(img2), cv2.COLOR_RGB2BGR)
img2 = cv2.cvtColor(img2, cv2.COLOR_BGR2GRAY)
# 2. use sift to extract keypoints and descriptors
# Initiate SIFT detector
sift = cv2.SIFT_create()
# find the keypoints and descriptors with SIFT
kp1, des1 = sift.detectAndCompute(img1, None)
kp2, des2 = sift.detectAndCompute(img2, None)
# BFMatcher with default params
bf = cv2.BFMatcher()
# bf = cv2.BFMatcher(cv2.NORM_L2, crossCheck=True)
# bf = cv2.BFMatcher(cv2.NORM_HAMMING, crossCheck=True)
matches = bf.knnMatch(des1, des2, k=2)
# Apply ratio test
good = []
point_list = []
distance_list = []
if method in ['max_score', 'max_score_even']:
matches = sorted(matches, key=lambda x: x[0].distance / x[1].distance)
anchor_points_list = []
for m, n in matches[:topk]:
print(m.distance / n.distance)
# check evenly distributed
if method == 'max_score_even':
to_close = False
for anchor_point in anchor_points_list:
pt1 = kp1[m.queryIdx].pt
dist = np.linalg.norm(np.array(pt1) - np.array(anchor_point))
if dist < 50:
to_close = True
break
if to_close:
continue
good.append([m])
pt1 = kp1[m.queryIdx].pt
pt2 = kp2[m.trainIdx].pt
dist = np.linalg.norm(np.array(pt1) - np.array(pt2))
distance_list.append(dist)
anchor_points_list.append(pt1)
pt1 = torch.tensor(pt1)
pt2 = torch.tensor(pt2)
pt = torch.stack([pt1, pt2]) # (2, 2)
point_list.append(pt)
if method in ['max_dist', 'random']:
for m, n in matches:
if m.distance < thr * n.distance:
good.append([m])
pt1 = kp1[m.queryIdx].pt
pt2 = kp2[m.trainIdx].pt
dist = np.linalg.norm(np.array(pt1) - np.array(pt2))
distance_list.append(dist)
pt1 = torch.tensor(pt1)
pt2 = torch.tensor(pt2)
pt = torch.stack([pt1, pt2]) # (2, 2)
point_list.append(pt)
distance_list = np.array(distance_list)
# only keep the points with the largest topk distance
idx = np.argsort(distance_list)
if method == "max_dist":
idx = idx[-topk:]
elif method == "random":
topk = min(topk, len(idx))
idx = np.random.choice(idx, topk, replace=False)
elif method == "max_score":
import pdb; pdb.set_trace()
raise NotImplementedError
# idx = np.argsort(distance_list)[:topk]
else:
raise ValueError(f"Unknown method {method}")
point_list = [point_list[i] for i in idx]
good = [good[i] for i in idx]
# # cv2.drawMatchesKnn expects list of lists as matches.
# draw_params = dict(
# matchColor=(255, 0, 0),
# singlePointColor=None,
# flags=2,
# )
# img3 = cv2.drawMatchesKnn(img1, kp1, img2, kp2, good, None, **draw_params)
# # manually draw the matches, the images are put in horizontal
# img3 = np.concatenate([img1_rgb, img2_rgb], axis=1) # (h, 2w, 3)
# for m in good:
# pt1 = kp1[m[0].queryIdx].pt
# pt2 = kp2[m[0].trainIdx].pt
# pt1 = (int(pt1[0]), int(pt1[1]))
# pt2 = (int(pt2[0]) + img1_rgb.shape[1], int(pt2[1]))
# cv2.line(img3, pt1, pt2, (255, 0, 0), 1)
# manually draw the matches, the images are put in vertical. with 10 pixels margin
margin = 10
img3 = np.zeros((img1_rgb.shape[0] + img2_rgb.shape[0] + margin, max(img1_rgb.shape[1], img2_rgb.shape[1]), 3), dtype=np.uint8)
# the margin is white
img3[:, :] = 255
img3[:img1_rgb.shape[0], :img1_rgb.shape[1]] = img1_rgb
img3[img1_rgb.shape[0] + margin:, :img2_rgb.shape[1]] = img2_rgb
# create a color list of 6 different colors
color_list = [(255, 0, 0), (0, 255, 0), (0, 0, 255), (255, 255, 0), (0, 255, 255), (255, 0, 255)]
for color_idx, m in enumerate(good):
pt1 = kp1[m[0].queryIdx].pt
pt2 = kp2[m[0].trainIdx].pt
pt1 = (int(pt1[0]), int(pt1[1]))
pt2 = (int(pt2[0]), int(pt2[1]) + img1_rgb.shape[0] + margin)
# cv2.line(img3, pt1, pt2, (255, 0, 0), 1)
# avoid the zigzag artifact in line
# random_color = tuple(np.random.randint(0, 255, 3).tolist())
color = color_list[color_idx % len(color_list)]
cv2.line(img3, pt1, pt2, color, 1, lineType=cv2.LINE_AA)
# add a empty circle to both start and end points
cv2.circle(img3, pt1, 3, color, lineType=cv2.LINE_AA)
cv2.circle(img3, pt2, 3, color, lineType=cv2.LINE_AA)
Image.fromarray(img3).save(output_path)
print(f"Save the sift matches to {output_path}")
# (f, topk, 2), f=2 (before interpolation)
if len(point_list) == 0:
return None
point_list = torch.stack(point_list)
point_list = point_list.permute(1, 0, 2)
return point_list
def interpolate_trajectory(points_torch, num_frames, t=None):
# points:(f, topk, 2), f=2 (before interpolation)
num_points = points_torch.shape[1]
points_torch = points_torch.permute(1, 0, 2) # (topk, f, 2)
points_list = []
for i in range(num_points):
# points:(f, 2)
points = points_torch[i].cpu().numpy()
x = [point[0] for point in points]
y = [point[1] for point in points]
if t is None:
t = np.linspace(0, 1, len(points))
# fx = interp1d(t, x, kind='cubic')
# fy = interp1d(t, y, kind='cubic')
fx = PchipInterpolator(t, x)
fy = PchipInterpolator(t, y)
new_t = np.linspace(0, 1, num_frames)
new_x = fx(new_t)
new_y = fy(new_t)
new_points = list(zip(new_x, new_y))
points_list.append(new_points)
points = torch.tensor(points_list) # (topk, num_frames, 2)
points = points.permute(1, 0, 2) # (num_frames, topk, 2)
return points
# diffusion feature matching
def point_tracking(
F0,
F1,
handle_points,
handle_points_init,
track_dist=5,
):
# handle_points: (num_points, 2)
# NOTE:
# 1. all row and col are reversed
# 2. handle_points in (y, x), not (x, y)
# reverse row and col
handle_points = torch.stack([handle_points[:, 1], handle_points[:, 0]], dim=-1)
handle_points_init = torch.stack([handle_points_init[:, 1], handle_points_init[:, 0]], dim=-1)
with torch.no_grad():
_, _, max_r, max_c = F0.shape
for i in range(len(handle_points)):
pi0, pi = handle_points_init[i], handle_points[i]
f0 = F0[:, :, int(pi0[0]), int(pi0[1])]
r1, r2 = max(0, int(pi[0]) - track_dist), min(max_r, int(pi[0]) + track_dist + 1)
c1, c2 = max(0, int(pi[1]) - track_dist), min(max_c, int(pi[1]) + track_dist + 1)
F1_neighbor = F1[:, :, r1:r2, c1:c2]
all_dist = (f0.unsqueeze(dim=-1).unsqueeze(dim=-1) - F1_neighbor).abs().sum(dim=1)
all_dist = all_dist.squeeze(dim=0)
row, col = divmod(all_dist.argmin().item(), all_dist.shape[-1])
# handle_points[i][0] = pi[0] - track_dist + row
# handle_points[i][1] = pi[1] - track_dist + col
handle_points[i][0] = r1 + row
handle_points[i][1] = c1 + col
handle_points = torch.stack([handle_points[:, 1], handle_points[:, 0]], dim=-1) # (num_points, 2)
return handle_points