Text-to-3D
image-to-3d
code / utils.py
Chao Xu
code pruning
216282e
import os
import json
import numpy as np
import cv2
from PIL import Image
# contrast correction, rescale and recenter
def image_preprocess_nosave(input_image, lower_contrast=True, rescale=True):
image_arr = np.array(input_image)
in_w, in_h = image_arr.shape[:2]
if lower_contrast:
alpha = 0.8 # Contrast control (1.0-3.0)
beta = 0 # Brightness control (0-100)
# Apply the contrast adjustment
image_arr = cv2.convertScaleAbs(image_arr, alpha=alpha, beta=beta)
image_arr[image_arr[...,-1]>200, -1] = 255
ret, mask = cv2.threshold(np.array(input_image.split()[-1]), 0, 255, cv2.THRESH_BINARY)
x, y, w, h = cv2.boundingRect(mask)
max_size = max(w, h)
ratio = 0.75
if rescale:
side_len = int(max_size / ratio)
else:
side_len = in_w
padded_image = np.zeros((side_len, side_len, 4), dtype=np.uint8)
center = side_len//2
padded_image[center-h//2:center-h//2+h, center-w//2:center-w//2+w] = image_arr[y:y+h, x:x+w]
rgba = Image.fromarray(padded_image).resize((256, 256), Image.LANCZOS)
rgba_arr = np.array(rgba) / 255.0
rgb = rgba_arr[...,:3] * rgba_arr[...,-1:] + (1 - rgba_arr[...,-1:])
return Image.fromarray((rgb * 255).astype(np.uint8))
# pose generation
def calc_pose(phis, thetas, size, radius = 1.2, device='cuda'):
import torch
def normalize(vectors):
return vectors / (torch.norm(vectors, dim=-1, keepdim=True) + 1e-10)
thetas = torch.FloatTensor(thetas).to(device)
phis = torch.FloatTensor(phis).to(device)
centers = torch.stack([
radius * torch.sin(thetas) * torch.sin(phis),
-radius * torch.cos(thetas) * torch.sin(phis),
radius * torch.cos(phis),
], dim=-1) # [B, 3]
# lookat
forward_vector = normalize(centers).squeeze(0)
up_vector = torch.FloatTensor([0, 0, 1]).to(device).unsqueeze(0).repeat(size, 1)
right_vector = normalize(torch.cross(up_vector, forward_vector, dim=-1))
if right_vector.pow(2).sum() < 0.01:
right_vector = torch.FloatTensor([0, 1, 0]).to(device).unsqueeze(0).repeat(size, 1)
up_vector = normalize(torch.cross(forward_vector, right_vector, dim=-1))
poses = torch.eye(4, dtype=torch.float, device=device)[:3].unsqueeze(0).repeat(size, 1, 1)
poses[:, :3, :3] = torch.stack((right_vector, up_vector, forward_vector), dim=-1)
poses[:, :3, 3] = centers
return poses
def get_poses(init_elev):
mid = init_elev
deg = 10
if init_elev <= 75:
low = init_elev + 30
# e.g. 30, 60, 20, 40, 30, 30, 50, 70, 50, 50
elevations = np.radians([mid]*4 + [low]*4 + [mid-deg,mid+deg,mid,mid]*4 + [low-deg,low+deg,low,low]*4)
img_ids = [f"{num}.png" for num in range(8)] + [f"{num}_{view_num}.png" for num in range(8) for view_num in range(4)]
else:
high = init_elev - 30
elevations = np.radians([mid]*4 + [high]*4 + [mid-deg,mid+deg,mid,mid]*4 + [high-deg,high+deg,high,high]*4)
img_ids = [f"{num}.png" for num in list(range(4)) + list(range(8,12))] + \
[f"{num}_{view_num}.png" for num in list(range(4)) + list(range(8,12)) for view_num in range(4)]
overlook_theta = [30+x*90 for x in range(4)]
eyelevel_theta = [60+x*90 for x in range(4)]
source_theta_delta = [0, 0, -deg, deg]
azimuths = np.radians(overlook_theta + eyelevel_theta + \
[view_theta + source for view_theta in overlook_theta for source in source_theta_delta] + \
[view_theta + source for view_theta in eyelevel_theta for source in source_theta_delta])
return img_ids, calc_pose(elevations, azimuths, len(azimuths)).cpu().numpy()
def gen_poses(shape_dir, pose_est):
img_ids, input_poses = get_poses(pose_est)
out_dict = {}
focal = 560/2; h = w = 256
out_dict['intrinsics'] = [[focal, 0, w / 2], [0, focal, h / 2], [0, 0, 1]]
out_dict['near_far'] = [1.2-0.7, 1.2+0.7]
out_dict['c2ws'] = {}
for view_id, img_id in enumerate(img_ids):
pose = input_poses[view_id]
pose = pose.tolist()
pose = [pose[0], pose[1], pose[2], [0, 0, 0, 1]]
out_dict['c2ws'][img_id] = pose
json_path = os.path.join(shape_dir, 'pose.json')
with open(json_path, 'w') as f:
json.dump(out_dict, f, indent=4)