# # Copyright (C) 2023, Inria # GRAPHDECO research group, https://team.inria.fr/graphdeco # All rights reserved. # # This software is free for non-commercial, research and evaluation use # under the terms of the LICENSE.md file. # # For inquiries contact george.drettakis@inria.fr # import os import sys from PIL import Image from typing import NamedTuple from scene.colmap_loader import read_extrinsics_text, read_intrinsics_text, qvec2rotmat, \ read_extrinsics_binary, read_intrinsics_binary, read_points3D_binary, read_points3D_text from utils.graphics_utils import getWorld2View2, focal2fov, fov2focal import numpy as np import json from pathlib import Path from plyfile import PlyData, PlyElement from utils.sh_utils import SH2RGB from scene.gaussian_model import BasicPointCloud import copy import pickle import natsort class CameraInfo(NamedTuple): uid: int R: np.array T: np.array FovY: np.array FovX: np.array image: np.array image_path: str image_name: str width: int height: int class SceneInfo(NamedTuple): point_cloud: BasicPointCloud train_cameras: list test_cameras: list nerf_normalization: dict ply_path: str def getNerfppNorm(cam_info): def get_center_and_diag(cam_centers): cam_centers = np.hstack(cam_centers) avg_cam_center = np.mean(cam_centers, axis=1, keepdims=True) center = avg_cam_center dist = np.linalg.norm(cam_centers - center, axis=0, keepdims=True) diagonal = np.max(dist) return center.flatten(), diagonal cam_centers = [] for cam in cam_info: W2C = getWorld2View2(cam.R, cam.T) C2W = np.linalg.inv(W2C) cam_centers.append(C2W[:3, 3:4]) center, diagonal = get_center_and_diag(cam_centers) radius = diagonal * 1.1 translate = -center return {"translate": translate, "radius": radius} def readColmapCameras(cam_extrinsics, cam_intrinsics, images_folder): cam_infos = [] for idx, key in enumerate(cam_extrinsics): sys.stdout.write('\r') # the exact output you're looking for: sys.stdout.write("Reading camera {}/{}".format(idx+1, len(cam_extrinsics))) sys.stdout.flush() extr = cam_extrinsics[key] intr = cam_intrinsics[extr.camera_id] height = intr.height width = intr.width uid = intr.id R = np.transpose(qvec2rotmat(extr.qvec)) T = np.array(extr.tvec) if intr.model=="SIMPLE_PINHOLE": focal_length_x = intr.params[0] FovY = focal2fov(focal_length_x, height) FovX = focal2fov(focal_length_x, width) elif intr.model=="PINHOLE": focal_length_x = intr.params[0] focal_length_y = intr.params[1] FovY = focal2fov(focal_length_y, height) FovX = focal2fov(focal_length_x, width) elif intr.model == "SIMPLE_RADIAL": focal_length_x = intr.params[0] # f FovY = focal2fov(focal_length_x, height) FovX = focal2fov(focal_length_x, width) else: assert False, "Colmap camera model not handled: only undistorted datasets (PINHOLE or SIMPLE_PINHOLE cameras) supported!" image_path = os.path.join(images_folder, os.path.basename(extr.name)) image_name = os.path.basename(image_path).split(".")[0] if 'llff' in image_path: dir_name = os.path.dirname(images_folder) base_name = os.path.basename(images_folder) scene_name = os.path.basename(dir_name) orig_folder = os.path.join(dir_name, 'images') if os.path.isdir(orig_folder): orig_files = os.listdir(orig_folder) else: print(f"Warning: LLFF original image folder not found: {orig_folder}; using {images_folder} for name matching.") orig_folder = images_folder orig_files = os.listdir(orig_folder) orig_files = natsort.natsorted(orig_files) cur_files = os.listdir(images_folder) cur_files = natsort.natsorted(cur_files) if not len(cur_files) == len(orig_files): assert len(cur_files) == len(orig_files) matching_index = next((i for i, name in enumerate(orig_files) if image_name in name), None) image_name = cur_files[matching_index].split('.')[0] image_path = os.path.join(images_folder, cur_files[matching_index]) if not os.path.exists(image_path): dir_name = os.path.dirname(image_path) filename = os.path.basename(image_path).split(".")[0] + '.png' image_path = os.path.join(dir_name, filename) try: image = Image.open(image_path) except: print("Image not found: ", image_path, "!!! *** Attention ***") # get rid of too many opened files image = copy.deepcopy(image) cam_info = CameraInfo(uid=uid, R=R, T=T, FovY=FovY, FovX=FovX, image=image, image_path=image_path, image_name=image_name, width=width, height=height) cam_infos.append(cam_info) sys.stdout.write('\n') return cam_infos def fetchPly(path): plydata = PlyData.read(path) vertices = plydata['vertex'] positions = np.vstack([vertices['x'], vertices['y'], vertices['z']]).T colors = np.vstack([vertices['red'], vertices['green'], vertices['blue']]).T / 255.0 normals = np.vstack([vertices['nx'], vertices['ny'], vertices['nz']]).T return BasicPointCloud(points=positions, colors=colors, normals=normals) def storePly(path, xyz, rgb): # Define the dtype for the structured array dtype = [('x', 'f4'), ('y', 'f4'), ('z', 'f4'), ('nx', 'f4'), ('ny', 'f4'), ('nz', 'f4'), ('red', 'u1'), ('green', 'u1'), ('blue', 'u1')] normals = np.zeros_like(xyz) elements = np.empty(xyz.shape[0], dtype=dtype) attributes = np.concatenate((xyz, normals, rgb), axis=1) elements[:] = list(map(tuple, attributes)) # Create the PlyData object and write to file vertex_element = PlyElement.describe(elements, 'vertex') ply_data = PlyData([vertex_element]) ply_data.write(path) def readColmapSceneInfo(path, images, eval, llffhold=8, resolution=1, cam_info_path=None): try: cameras_extrinsic_file = os.path.join(path, "sparse/0", "images.bin") cameras_intrinsic_file = os.path.join(path, "sparse/0", "cameras.bin") cam_extrinsics = read_extrinsics_binary(cameras_extrinsic_file) cam_intrinsics = read_intrinsics_binary(cameras_intrinsic_file) except: cameras_extrinsic_file = os.path.join(path, "sparse/0", "images.txt") cameras_intrinsic_file = os.path.join(path, "sparse/0", "cameras.txt") cam_extrinsics = read_extrinsics_text(cameras_extrinsic_file) cam_intrinsics = read_intrinsics_text(cameras_intrinsic_file) reading_dir = "images" if images == None else images if resolution > 1: reading_dir = reading_dir + f"_{resolution}" cam_infos_unsorted = readColmapCameras(cam_extrinsics=cam_extrinsics, cam_intrinsics=cam_intrinsics, images_folder=os.path.join(path, reading_dir)) cam_infos = sorted(cam_infos_unsorted.copy(), key = lambda x : x.image_name) if eval: train_cam_infos = [c for idx, c in enumerate(cam_infos) if idx % llffhold != 0] test_cam_infos = [c for idx, c in enumerate(cam_infos) if idx % llffhold == 0] else: train_cam_infos = cam_infos test_cam_infos = [] nerf_normalization = getNerfppNorm(train_cam_infos) ply_path = os.path.join(path, "sparse/0/points3D.ply") bin_path = os.path.join(path, "sparse/0/points3D.bin") txt_path = os.path.join(path, "sparse/0/points3D.txt") if not os.path.exists(ply_path): print("Converting point3d.bin to .ply, will happen only the first time you open the scene.") try: xyz, rgb, _ = read_points3D_binary(bin_path) except: xyz, rgb, _ = read_points3D_text(txt_path) storePly(ply_path, xyz, rgb) try: pcd = fetchPly(ply_path) except: pcd = None scene_info = SceneInfo(point_cloud=pcd, train_cameras=train_cam_infos, test_cameras=test_cam_infos, nerf_normalization=nerf_normalization, ply_path=ply_path) return scene_info def readCamerasFromTransforms(path, transformsfile, white_background, extension=".png", resolution=1, get_spiral=False): cam_infos = [] with open(os.path.join(path, transformsfile)) as json_file: contents = json.load(json_file) fovx = contents["camera_angle_x"] frames = contents["frames"] for idx, frame in enumerate(frames): # if resolution > 1: # folder_name = frame["file_path"].split("/")[1] + f"_{resolution}" # img_name = frame["file_path"].split("/")[2] # cam_name = os.path.join(path, folder_name, img_name + extension) # else: cam_name = os.path.join(path, frame["file_path"] + extension) # NeRF 'transform_matrix' is a camera-to-world transform c2w = np.array(frame["transform_matrix"]) # change from OpenGL/Blender camera axes (Y up, Z back) to COLMAP (Y down, Z forward) c2w[:3, 1:3] *= -1 # get the world-to-camera transform and set R, T w2c = np.linalg.inv(c2w) R = np.transpose(w2c[:3,:3]) # R is stored transposed due to 'glm' in CUDA code T = w2c[:3, 3] image_path = os.path.join(path, cam_name) image_name = Path(cam_name).stem image = Image.open(image_path) im_data = np.array(image.convert("RGBA")) bg = np.array([1,1,1]) if white_background else np.array([0, 0, 0]) norm_data = im_data / 255.0 arr = norm_data[:,:,:3] * norm_data[:, :, 3:4] + bg * (1 - norm_data[:, :, 3:4]) image = Image.fromarray(np.array(arr*255.0, dtype=np.byte), "RGB") fovy = focal2fov(fov2focal(fovx, image.size[0]), image.size[1]) FovY = fovy FovX = fovx cam_infos.append(CameraInfo(uid=idx, R=R, T=T, FovY=FovY, FovX=FovX, image=image, image_path=image_path, image_name=image_name, width=image.size[0], height=image.size[1])) return cam_infos def readNerfSyntheticInfo(path, white_background, eval, extension=".png", resolution=1): print("Reading Training Transforms") train_cam_infos = readCamerasFromTransforms(path, "transforms_train.json", white_background, extension, resolution=resolution) print("Reading Test Transforms") test_cam_infos = readCamerasFromTransforms(path, "transforms_test.json", white_background, extension, resolution=resolution) if not eval: train_cam_infos.extend(test_cam_infos) test_cam_infos = [] nerf_normalization = getNerfppNorm(train_cam_infos) ply_path = os.path.join(path, "points3d.ply") if not os.path.exists(ply_path): # Since this data set has no colmap data, we start with random points num_pts = 100_000 print(f"Generating random point cloud ({num_pts})...") # We create random points inside the bounds of the synthetic Blender scenes xyz = np.random.random((num_pts, 3)) * 2.6 - 1.3 shs = np.random.random((num_pts, 3)) / 255.0 pcd = BasicPointCloud(points=xyz, colors=SH2RGB(shs), normals=np.zeros((num_pts, 3))) storePly(ply_path, xyz, SH2RGB(shs) * 255) try: pcd = fetchPly(ply_path) except: pcd = None scene_info = SceneInfo(point_cloud=pcd, train_cameras=train_cam_infos, test_cameras=test_cam_infos, nerf_normalization=nerf_normalization, ply_path=ply_path) return scene_info def readMultiScale(path, white_background,split, only_highres=False): cam_infos = [] print("read split:", split) with open(os.path.join(path, 'metadata.json'), 'r') as fp: meta = json.load(fp)[split] meta = {k: np.array(meta[k]) for k in meta} # should now have ['pix2cam', 'cam2world', 'width', 'height'] in self.meta for idx, relative_path in enumerate(meta['file_path']): if only_highres and not relative_path.endswith("d0.png"): continue image_path = os.path.join(path, relative_path) image_name = Path(image_path).stem # NeRF 'transform_matrix' is a camera-to-world transform c2w = meta["cam2world"][idx] # change from OpenGL/Blender camera axes (Y up, Z back) to COLMAP (Y down, Z forward) c2w[:3, 1:3] *= -1 # get the world-to-camera transform and set R, T w2c = np.linalg.inv(c2w) R = np.transpose(w2c[:3,:3]) # R is stored transposed due to 'glm' in CUDA code T = w2c[:3, 3] image = Image.open(image_path) im_data = np.array(image.convert("RGBA")) bg = np.array([1,1,1]) if white_background else np.array([0, 0, 0]) norm_data = im_data / 255.0 arr = norm_data[:,:,:3] * norm_data[:, :, 3:4] + bg * (1 - norm_data[:, :, 3:4]) image = Image.fromarray(np.array(arr*255.0, dtype=np.byte), "RGB") fovx = focal2fov(meta["focal"][idx], image.size[0]) fovy = focal2fov(meta["focal"][idx], image.size[1]) FovY = fovy FovX = fovx cam_infos.append(CameraInfo(uid=idx, R=R, T=T, FovY=FovY, FovX=FovX, image=image, image_path=image_path, image_name=image_name, width=image.size[0], height=image.size[1])) return cam_infos def readMultiScaleNerfSyntheticInfo(path, white_background, eval, load_allres=False): print("Reading train from metadata.json") train_cam_infos = readMultiScale(path, white_background, "train", only_highres=(not load_allres)) print("number of training images:", len(train_cam_infos)) print("Reading test from metadata.json") test_cam_infos = readMultiScale(path, white_background, "test", only_highres=False) print("number of testing images:", len(test_cam_infos)) if not eval: print("adding test cameras to training") train_cam_infos.extend(test_cam_infos) test_cam_infos = [] nerf_normalization = getNerfppNorm(train_cam_infos) ply_path = os.path.join(path, "points3d.ply") if not os.path.exists(ply_path): # Since this data set has no colmap data, we start with random points num_pts = 100_000 print(f"Generating random point cloud ({num_pts})...") # We create random points inside the bounds of the synthetic Blender scenes xyz = np.random.random((num_pts, 3)) * 2.6 - 1.3 shs = np.random.random((num_pts, 3)) / 255.0 pcd = BasicPointCloud(points=xyz, colors=SH2RGB(shs), normals=np.zeros((num_pts, 3))) storePly(ply_path, xyz, SH2RGB(shs) * 255) try: pcd = fetchPly(ply_path) except: pcd = None scene_info = SceneInfo(point_cloud=pcd, train_cameras=train_cam_infos, test_cameras=test_cam_infos, nerf_normalization=nerf_normalization, ply_path=ply_path) return scene_info sceneLoadTypeCallbacks = { "Colmap": readColmapSceneInfo, "Blender" : readNerfSyntheticInfo, "Multi-scale": readMultiScaleNerfSyntheticInfo, }