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import collections
import json
import os
import matplotlib.pyplot as plt
import numpy as np
import torch
import scipy
from mat73 import loadmat
from .utils import Rays
from tqdm import tqdm
import sys
sys.path.append(os.path.dirname(os.path.dirname(os.path.abspath(__file__))))
from misc.dataset_utils import read_h5
def _load_renderings(root_fp: str, subject_id: str, split: str, have_images=True, img_shape=(256, 256)):
"""Load images from disk."""
if not root_fp.startswith("/"):
# allow relative path. e.g., "./data/nerf_synthetic/"
root_fp = os.path.join(
os.path.dirname(os.path.abspath(__file__)),
"..",
"..",
root_fp,
)
data_dir = root_fp
with open(
os.path.join(data_dir, "transforms_{}.json".format(split)), "r"
) as fp:
meta = json.load(fp)
images = []
camtoworlds = []
if have_images:
for i in range(len(meta["frames"])):
frame = meta["frames"][i]
number = int(frame["file_path"].split("_")[-1])
fname = os.path.join(data_dir, f"{number:03d}" + ".png")
# fname = os.path.join(data_dir, frame["file_path"] + ".png")
rgba = imageio.imread(fname)
camtoworlds.append(frame["transform_matrix"])
images.append(rgba)
images = np.stack(images, axis=0)
camtoworlds = np.stack(camtoworlds, axis=0)
h, w = images.shape[1:3]
else:
for i in range(len(meta["frames"])):
frame = meta["frames"][i]
camtoworlds.append(frame["transform_matrix"])
camtoworlds = np.stack(camtoworlds, axis=0)
h, w = img_shape
camera_angle_x = float(meta["camera_angle_x"])
focal = 0.5 * w / np.tan(0.5 * camera_angle_x)
return images, camtoworlds, focal
def _parse_shift_for_grid(shift, img_shape):
h, w = int(img_shape[0]), int(img_shape[1])
arr = np.asarray(shift, dtype=np.float32)
if arr.ndim == 0:
return float(arr.item()), None
arr = arr.squeeze()
if arr.ndim == 0 or arr.size == 1:
return float(arr.reshape(-1)[0]), None
if arr.ndim == 1 and arr.size == h * w:
return 0.0, torch.from_numpy(arr.reshape(h, w))
if arr.ndim == 2 and arr.shape == (h, w):
return 0.0, torch.from_numpy(arr)
# Fallback to legacy behavior: use first value only.
return float(arr.reshape(-1)[0]), None
def _load_renderings_transient_real(root_fp: str, subject_id: str, split: str, have_images=True, img_shape=(256, 256), n_bins=4096, shift=0, bin_width_s=4e-12):
"""Load images from disk."""
data_dir = root_fp
with open(
os.path.join(data_dir, "transforms_{}.json".format(split)), "r"
) as fp:
meta = json.load(fp)
images = []
camtoworlds = []
exposure_time = 299792458 * float(bin_width_s)
shift_scalar, shift_map = _parse_shift_for_grid(shift, img_shape)
x = (torch.arange(img_shape[0], device="cpu")-img_shape[0]//2+0.5)/(img_shape[0]//2-0.5)
y = (torch.arange(img_shape[0], device="cpu")-img_shape[0]//2+0.5)/(img_shape[0]//2-0.5)
z = torch.arange(n_bins*2, device="cpu").float()
X, Y, Z = torch.meshgrid(x, y, z, indexing="xy")
Z = Z*exposure_time/2
if shift_map is not None:
Z = Z - shift_map[..., None]
else:
Z = Z - float(shift_scalar)
Z = Z*2/exposure_time
Z = (Z-n_bins*2//2+0.5)/(n_bins*2//2-0.5)
grid = torch.stack((Z, X, Y), dim=-1)[None, ...]
del X
del Y
del Z
if have_images:
tqdm.write('Loading data')
for i in tqdm(range(len(meta["frames"]))):
frame = meta["frames"][i]
number = int(frame["file_path"].split("_")[-1])
fname = os.path.join(os.path.join(data_dir, "../.."), f"transient{number:03d}.pt")
rgba = torch.load(fname).to_dense()
rgba = torch.Tensor(rgba)[..., :3000].float().cpu()
# if img_shape[0]==256:
# rgba = (rgba[::2, ::2] + rgba[::2, 1::2] + rgba[1::2, ::2]+ rgba[1::2, 1::2] )/4
rgba = torch.nn.functional.grid_sample(rgba[None, None, ...], grid, align_corners=True).squeeze().cpu()
rgba = (rgba[..., 1::2]+ rgba[..., ::2] )/2
camtoworlds.append(frame["transform_matrix"])
rgba = torch.clip(rgba, 0, None)
rgba = rgba[..., None].repeat(1, 1, 1, 3)
images.append(rgba)
images = torch.stack(images, axis=0)
max = torch.max(images)
images /= torch.max(images)
if split == "test":
quotient = images.shape[1]//img_shape[0]
times_downsample = int(np.log2(quotient))
for i in range(times_downsample):
images = (images[:, 1::2, ::2] + images[:, ::2, ::2] + images[:, 1::2, 1::2] + images[:, ::2, 1::2])/4
camtoworlds = np.stack(camtoworlds, axis=0)
h, w = images.shape[1:3]
else:
for i in range(len(meta["frames"])):
frame = meta["frames"][i]
camtoworlds.append(frame["transform_matrix"])
camtoworlds = np.stack(camtoworlds, axis=0)
max = 1
h, w = img_shape
return images, camtoworlds, max
class SubjectLoaderTransientReal(torch.utils.data.Dataset):
"""Single subject data loader for training and evaluation."""
SPLITS = ["train", "val", "trainval", "test"]
SUBJECT_IDS = [
"chair",
"drums",
"ficus",
"hotdog",
"lego",
"materials",
"mic",
"ship",
]
# WIDTH, HEIGHT = 64, 64
NEAR, FAR = 0, 6
OPENGL_CAMERA = True
def __init__(
self,
subject_id: str,
root_fp: str,
split: str,
color_bkgd_aug: str = "black",
num_rays: int = None,
near: float = None,
far: float = None,
batch_over_images: bool = True,
have_images=True,
img_shape=(256, 256),
n_bins=10000,
rfilter_sigma=0.15,
sample_as_per_distribution = True,
shift = 0.3,
testing =False
):
super().__init__()
#assert split in self.SPLITS, "%s" % split
# assert subject_id in self.SUBJECT_IDS, "%s" % subject_id
assert color_bkgd_aug in ["white", "black", "random"]
self.sample_as_per_distribution = sample_as_per_distribution
self.rfilter_sigma = rfilter_sigma
self.HEIGHT, self.WIDTH = img_shape
self.split = split
self.testing = testing
self.num_rays = num_rays
self.near = self.NEAR if near is None else near
self.far = self.FAR if far is None else far
self.training = (num_rays is not None) and (
split in ["train", "trainval"]
)
self.shift = shift
self.testing = testing
self.rep = 1
self.color_bkgd_aug = color_bkgd_aug
self.batch_over_images = batch_over_images
self.have_images = have_images
self.n_bins = n_bins
shift = shift
if split == "trainval":
_images_train, _camtoworlds_train, _focal_train = _load_renderings_transient_real(
root_fp, subject_id, "train", n_bins=self.n_bins, shift=shift
)
_images_val, _camtoworlds_val, _focal_val = _load_renderings_transient_real(
root_fp, subject_id, "val", n_bins=self.n_bins, shift=shift
)
self.images = np.concatenate([_images_train, _images_val])
self.camtoworlds = np.concatenate(
[_camtoworlds_train, _camtoworlds_val]
)
self.focal = _focal_train
self.images = torch.from_numpy(self.images).to(torch.float32)
# ste for transient
self.images = torch.reshape(self.images, (-1, self.HEIGHT, self.WIDTH, self.n_bins*3))
elif have_images:
self.images, self.camtoworlds, self.focal = _load_renderings_transient_real(
root_fp, subject_id, split, n_bins=self.n_bins, shift=shift, img_shape=img_shape
)
self.images =self.images.to(torch.float32)
assert self.images.shape[1:3] == (self.HEIGHT, self.WIDTH)
else:
_, self.camtoworlds, self.focal = _load_renderings(
root_fp, subject_id, split, have_images=have_images, img_shape=img_shape
)
self.max = self.focal
self.camtoworlds = torch.from_numpy(self.camtoworlds).to(torch.float32)
self.camtoworlds[:, :3, 3] = self.camtoworlds[:, :3, 3]
# self.K = LearnRays(params["rays"], img_shape=(self.WIDTH, self.HEIGHT))
def __len__(self):
return len(self.camtoworlds)
# @torch.no_grad()
def __getitem__(self, index):
data = self.fetch_data(index)
data = self.preprocess(data)
return data
def preprocess(self, data):
"""Process the fetched / cached data with randomness."""
rgba, rays = data["rgba"], data["rays"]
# pixels, alpha = torch.split(rgba, [3, 1], dim=-1)
if rgba is not None:
pixels = rgba.to(self.camtoworlds.device)
else:
pixels = rgba
if self.color_bkgd_aug == "random":
color_bkgd = torch.rand(3, device=self.camtoworlds.device)
elif self.color_bkgd_aug == "white":
color_bkgd = torch.ones(3, device=self.camtoworlds.device)
elif self.color_bkgd_aug == "black":
color_bkgd = torch.zeros(3, device=self.camtoworlds.device)
# pixels = pixels * alpha + color_bkgd * (1.0 - alpha)
return {
"pixels": pixels, # [n_rays, 3] or [h, w, 3]
"rays": rays, # [n_rays,] or [h, w]
"color_bkgd": color_bkgd, # [3,]
**{k: v for k, v in data.items() if k not in ["rgba", "rays"]},
}
def update_num_rays(self, num_rays):
self.num_rays = num_rays
def fetch_data(self, index, rep=None, num_rays=None):
"""Fetch the data (it maybe cached for multiple batches)."""
if num_rays==None:
num_rays = self.num_rays
if rep==None:
rep = self.rep
if self.training:
if self.batch_over_images:
image_id = torch.randint(
0,
len(self.images),
size=(num_rays,),
device=self.images.device,
)
else:
image_id = [index]
x = torch.randint(
0, self.WIDTH, size=(num_rays,), device="cpu"
)
y = torch.randint(
0, self.HEIGHT, size=(num_rays,), device="cpu"
)
x = x.repeat(rep)
y = y.repeat(rep)
image_id = image_id.repeat(rep)
rgba = self.images[image_id, y, x] # (num_rays, 4)
elif self.testing:
image_id = [index]
x, y = torch.meshgrid(
torch.arange(self.WIDTH, device="cpu"),
torch.arange(self.HEIGHT, device="cpu"),
indexing="xy",
)
x = x.flatten()
y = y.flatten()
x = x.repeat(rep)
y = y.repeat(rep)
# image_id = image_id.repeat(rep)
if self.have_images:
rgba = self.images[image_id, y, x] # (num_rays, 4)
else:
rgba = None
elif self.have_images:
image_id = [index]
x, y = torch.meshgrid(
torch.arange(self.WIDTH, device=self.camtoworlds.device),
torch.arange(self.HEIGHT, device=self.camtoworlds.device),
indexing="xy",
)
x = x.flatten()
y = y.flatten()
rgba = self.images[image_id, y, x] # (num_rays, 4)
else:
image_id = [index]
x, y = torch.meshgrid(
torch.arange(self.WIDTH, device=self.camtoworlds.device),
torch.arange(self.HEIGHT, device=self.camtoworlds.device),
indexing="xy",
)
x = x.flatten()
y = y.flatten()
# generate rays
scale = self.rfilter_sigma
c2w = self.camtoworlds[image_id]
bounds_max = [4*scale]*x.shape[0]
loc = 0
if self.training:
s_x, s_y, weights = spatial_filter(x, y, sigma=scale, rep = self.rep, prob_dithering=self.sample_as_per_distribution)
s_x = (torch.clip(x + torch.from_numpy(s_x), 0, self.WIDTH-1).to(self.camtoworlds.device)).to(torch.float32)
s_y = (torch.clip(y + torch.from_numpy(s_y), 0, self.HEIGHT-1).to(self.camtoworlds.device)).to(torch.float32)
weights = torch.Tensor(weights).to(self.camtoworlds.device)
elif self.testing:
s_x, s_y, weights = spatial_filter(x, y, sigma=scale, rep = self.rep, prob_dithering=self.sample_as_per_distribution)
s_x = (torch.clip(x + torch.from_numpy(s_x), 0, self.WIDTH-1).to(self.camtoworlds.device)).to(torch.float32)
s_y = (torch.clip(y + torch.from_numpy(s_y), 0, self.HEIGHT-1).to(self.camtoworlds.device)).to(torch.float32)
weights = torch.Tensor(weights).to(self.camtoworlds.device)
else:
s_x = x
s_y = y
camera_dirs = self.K(s_x, s_y)
directions = (camera_dirs[:, None, :] * c2w[:, :3, :3]).sum(dim=-1)
origins = torch.broadcast_to(c2w[:, :3, -1], directions.shape)
viewdirs = directions / torch.linalg.norm(
directions, dim=-1, keepdims=True
)
if self.training:
origins = torch.reshape(origins, (-1, 3))
viewdirs = torch.reshape(viewdirs, (-1, 3))
# here
rgba = torch.reshape(rgba, (-1,self.n_bins*3))
elif self.testing:
origins = torch.reshape(origins, (-1, 3))
viewdirs = torch.reshape(viewdirs, (-1, 3))
# here
if self.have_images:
rgba = torch.reshape(rgba, (-1,self.n_bins*3))
elif self.have_images:
origins = torch.reshape(origins, (self.HEIGHT, self.WIDTH, 3))
viewdirs = torch.reshape(viewdirs, (self.HEIGHT, self.WIDTH, 3))
rgba = torch.reshape(rgba, (self.HEIGHT, self.WIDTH, self.n_bins * 3))
else:
origins = torch.reshape(origins, (self.HEIGHT, self.WIDTH, 3))
viewdirs = torch.reshape(viewdirs, (self.HEIGHT, self.WIDTH, 3))
rgba = None
rays = Rays(origins=origins, viewdirs=viewdirs)
if self.training or self.testing:
return {
"rgba": rgba, # [h, w, 4] or [num_rays, 4]
"rays": rays, # [h, w, 3] or [num_rays, 3]
"weights":weights
}
return {
"rgba": rgba, # [h, w, 4] or [num_rays, 4]
"rays": rays, # [h, w, 3] or [num_rays, 3]
}
class LearnRays(torch.nn.Module):
def __init__(self, rays, device ="cuda:0", img_shape = (256, 256)):
"""
:param num_cams:
:param learn_R: True/False
:param learn_t: True/False
:param init_c2w: (N, 4, 4) torch tensor
"""
super(LearnRays, self).__init__()
self.device = device
self.init_c2w = None
self.img_shape = img_shape
x = np.arange(32, 480)
X, Y = np.meshgrid(x, x)
tar_x = np.arange(0, 512)
tar_X, tar_Y = np.meshgrid(tar_x, tar_x)
# rays = rays.detach().cpu().numpy()
ray_x = scipy.interpolate.interpn((x, x), rays[32:-32, 32:-32, 0].transpose(1, 0), np.stack([tar_X, tar_Y], axis=-1).squeeze().flatten(), bounds_error = False, fill_value=None).reshape(512, 512)
ray_y = scipy.interpolate.interpn((x, x), rays[32:-32, 32:-32, 1].transpose(1, 0), np.stack([tar_X, tar_Y], axis=-1).squeeze().flatten(), bounds_error = False, fill_value=None).reshape(512, 512)
ray_z = scipy.interpolate.interpn((x, x), rays[32:-32, 32:-32, 2].transpose(1, 0), np.stack([tar_X, tar_Y], axis=-1).squeeze().flatten(), bounds_error = False, fill_value=None).reshape(512, 512)
rays = torch.from_numpy(np.stack([ray_x, ray_y, ray_z], axis=-1)).to(self.device)
quotient = rays.shape[1]//img_shape[0]
times_downsample = int(np.log2(quotient))
for i in range(times_downsample):
rays = (rays[1::2, ::2] + rays[::2, ::2] + rays[1::2, 1::2] + rays[::2, 1::2])/4
rays = rays/torch.linalg.norm(rays, dim=-1, keepdims=True)
self.rays = rays
# self.rays = torch.nn.Parameter(rays, requires_grad=learn_rays)
def forward(self, x0, y0):
"""input coord = (n, 2)
rays = (512, 512, 3)
"""
rays = self.rays
x1, y1 = torch.floor(x0.float()), torch.floor(y0.float())
x2, y2 = x1+1, y1+1
"""
Perform bilinear interpolation to estimate the value of the function f(x, y)
at the continuous point (x0, y0), given that f is known at integer values of x, y.
"""
# if (y1>self.img_shape[0]-1).any() or (x1>self.img_shape[0]-1).any():
# print("hello")
x1, y1 = torch.clip(x1, 0, self.img_shape[0]-1), torch.clip(y1, 0, self.img_shape[0]-1)
# x2, y2 = torch.clip(x2, 0, self.img_shape[0]-1), torch.clip(y2, 0, self.img_shape[0]-1)
# Compute the weights for the interpolation
wx1 = ((x2 - x0) / (x2 - x1 + 1e-8))[:, None]
wx2 = ((x0 - x1) / (x2 - x1 + 1e-8))[:, None]
wy1 = ((y2 - y0) / (y2 - y1 + 1e-8))[:, None]
wy2 = ((y0 - y1) / (y2 - y1 + 1e-8))[:, None]
x1, y1, x2, y2 = x1.long(), y1.long(), x2.long(), y2.long()
x2, y2 = torch.clip(x2, 0, self.img_shape[0] - 1), torch.clip(y2, 0, self.img_shape[0] - 1)
# Compute the interpolated value of f(x, y) at (x0, y0)
f_interp = wx1 * wy1 * rays[y1, x1] + \
wx1 * wy2 * rays[y2, x1] + \
wx2 * wy1 * rays[y1, x2] + \
wx2 * wy2 * rays[y2, x2]
f_interp = f_interp/torch.linalg.norm(f_interp, dim=-1, keepdims=True)
return f_interp.float()
def spatial_filter(x, y, sigma, rep, prob_dithering=True):
pdf_fn = lambda x: np.exp(-x/(2*sigma**2)) - np.exp(-16)
if prob_dithering:
bounds_max = [4*sigma]*x.shape[0]
loc = 0
s_x = scipy.stats.truncnorm.rvs((-np.array(bounds_max)-loc)/sigma, (np.array(bounds_max)-loc)/sigma, loc=loc, scale=sigma)
s_y = scipy.stats.truncnorm.rvs((-np.array(bounds_max)-loc)/sigma, (np.array(bounds_max)-loc)/sigma, loc=loc, scale=sigma)
weights = np.ones_like(s_x)*1/rep
else:
s_x = np.random.uniform(low=-4*sigma, high=4*sigma, size=(rep, x.shape[0]//rep))
s_y = np.random.uniform(low=-4*sigma, high=4*sigma, size=(rep, x.shape[0]//rep))
dists = (s_x**2 + s_y**2)
weights = pdf_fn(dists)
weights = weights/weights.sum(0)[None, :]
s_x = s_x.flatten()
s_y = s_y.flatten()
weights = weights.flatten()
return s_x, s_y, weights