| 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("/"): |
| |
| 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") |
|
|
| |
| 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) |
|
|
| |
| 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() |
| |
| |
| |
| 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", |
| ] |
|
|
| |
| 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 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) |
|
|
| |
| 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] |
| |
|
|
|
|
|
|
| def __len__(self): |
| return len(self.camtoworlds) |
|
|
| |
| 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"] |
| |
|
|
| 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) |
|
|
| |
| return { |
| "pixels": pixels, |
| "rays": rays, |
| "color_bkgd": color_bkgd, |
| **{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] |
|
|
| 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) |
| |
| if self.have_images: |
| rgba = self.images[image_id, y, x] |
| 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] |
| 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() |
|
|
| |
| |
| 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)) |
| |
| rgba = torch.reshape(rgba, (-1,self.n_bins*3)) |
| elif self.testing: |
| origins = torch.reshape(origins, (-1, 3)) |
| viewdirs = torch.reshape(viewdirs, (-1, 3)) |
| |
| 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, |
| "rays": rays, |
| "weights":weights |
| } |
|
|
| return { |
| "rgba": rgba, |
| "rays": rays, |
| } |
|
|
|
|
|
|
|
|
|
|
| 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) |
| |
|
|
| 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 |
| |
|
|
| 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. |
| """ |
| |
| |
| x1, y1 = torch.clip(x1, 0, self.img_shape[0]-1), torch.clip(y1, 0, self.img_shape[0]-1) |
|
|
| |
|
|
| |
| 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) |
|
|
| |
| 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 |
|
|