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LucidDreamer / gaussian_renderer /__init__.py

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	#
	# 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 torch
	import math
	from diff_gaussian_rasterization import GaussianRasterizationSettings, GaussianRasterizer
	from scene.gaussian_model import GaussianModel
	from utils.sh_utils import eval_sh, SH2RGB
	from utils.graphics_utils import fov2focal
	import random


	def render(viewpoint_camera, pc : GaussianModel, pipe, bg_color : torch.Tensor, scaling_modifier = 1.0, black_video = False,
	override_color = None, sh_deg_aug_ratio = 0.1, bg_aug_ratio = 0.3, shs_aug_ratio=1.0, scale_aug_ratio=1.0, test = False):
	"""
	Render the scene.

	Background tensor (bg_color) must be on GPU!
	"""

	# Create zero tensor. We will use it to make pytorch return gradients of the 2D (screen-space) means
	screenspace_points = torch.zeros_like(pc.get_xyz, dtype=pc.get_xyz.dtype, requires_grad=True, device="cuda") + 0
	try:
	screenspace_points.retain_grad()
	except:
	pass

	if black_video:
	bg_color = torch.zeros_like(bg_color)
	#Aug
	if random.random() < sh_deg_aug_ratio and not test:
	act_SH = 0
	else:
	act_SH = pc.active_sh_degree

	if random.random() < bg_aug_ratio and not test:
	if random.random() < 0.5:
	bg_color = torch.rand_like(bg_color)
	else:
	bg_color = torch.zeros_like(bg_color)
	# bg_color = torch.zeros_like(bg_color)

	#bg_color = torch.zeros_like(bg_color)
	# Set up rasterization configuration
	tanfovx = math.tan(viewpoint_camera.FoVx * 0.5)
	tanfovy = math.tan(viewpoint_camera.FoVy * 0.5)
	try:
	raster_settings = GaussianRasterizationSettings(
	image_height=int(viewpoint_camera.image_height),
	image_width=int(viewpoint_camera.image_width),
	tanfovx=tanfovx,
	tanfovy=tanfovy,
	bg=bg_color,
	scale_modifier=scaling_modifier,
	viewmatrix=viewpoint_camera.world_view_transform,
	projmatrix=viewpoint_camera.full_proj_transform,
	sh_degree=act_SH,
	campos=viewpoint_camera.camera_center,
	prefiltered=False
	)
	except TypeError as e:
	raster_settings = GaussianRasterizationSettings(
	image_height=int(viewpoint_camera.image_height),
	image_width=int(viewpoint_camera.image_width),
	tanfovx=tanfovx,
	tanfovy=tanfovy,
	bg=bg_color,
	scale_modifier=scaling_modifier,
	viewmatrix=viewpoint_camera.world_view_transform,
	projmatrix=viewpoint_camera.full_proj_transform,
	sh_degree=act_SH,
	campos=viewpoint_camera.camera_center,
	prefiltered=False,
	debug=False
	)


	rasterizer = GaussianRasterizer(raster_settings=raster_settings)

	means3D = pc.get_xyz
	means2D = screenspace_points
	opacity = pc.get_opacity

	# If precomputed 3d covariance is provided, use it. If not, then it will be computed from
	# scaling / rotation by the rasterizer.
	scales = None
	rotations = None
	cov3D_precomp = None
	if pipe.compute_cov3D_python:
	cov3D_precomp = pc.get_covariance(scaling_modifier)
	else:
	scales = pc.get_scaling
	rotations = pc.get_rotation

	# If precomputed colors are provided, use them. Otherwise, if it is desired to precompute colors
	# from SHs in Python, do it. If not, then SH -> RGB conversion will be done by rasterizer.
	shs = None
	colors_precomp = None
	if colors_precomp is None:
	if pipe.convert_SHs_python:
	raw_rgb = pc.get_features.transpose(1, 2).view(-1, 3, (pc.max_sh_degree+1)**2).squeeze()[:,:3]
	rgb = torch.sigmoid(raw_rgb)
	colors_precomp = rgb
	else:
	shs = pc.get_features
	else:
	colors_precomp = override_color

	if random.random() < shs_aug_ratio and not test:
	variance = (0.2 ** 0.5) * shs
	shs = shs + (torch.randn_like(shs) * variance)

	# add noise to scales
	if random.random() < scale_aug_ratio and not test:
	variance = (0.2 ** 0.5) * scales / 4
	scales = torch.clamp(scales + (torch.randn_like(scales) * variance), 0.0)

	# Rasterize visible Gaussians to image, obtain their radii (on screen).

	rendered_image, radii, depth_alpha = rasterizer(
	means3D = means3D,
	means2D = means2D,
	shs = shs,
	colors_precomp = colors_precomp,
	opacities = opacity,
	scales = scales,
	rotations = rotations,
	cov3D_precomp = cov3D_precomp)
	depth, alpha = torch.chunk(depth_alpha, 2)
	# bg_train = pc.get_background
	# rendered_image = bg_train*alpha.repeat(3,1,1) + rendered_image
	# focal = 1 / (2 * math.tan(viewpoint_camera.FoVx / 2)) #torch.tan(torch.tensor(viewpoint_camera.FoVx) / 2) * (2. / 2
	# disparity = focal / (depth + 1e-9)
	# max_disp = torch.max(disparity)
	# min_disp = torch.min(disparity[disparity > 0])
	# norm_disparity = (disparity - min_disp) / (max_disp - min_disp)
	# # Those Gaussians that were frustum culled or had a radius of 0 were not visible.
	# # They will be excluded from value updates used in the splitting criteria.
	# return {"render": rendered_image,
	# "depth": norm_disparity,

	focal = 1 / (2 * math.tan(viewpoint_camera.FoVx / 2))
	disp = focal / (depth + (alpha * 10) + 1e-5)

	try:
	min_d = disp[alpha <= 0.1].min()
	except Exception:
	min_d = disp.min()

	disp = torch.clamp((disp - min_d) / (disp.max() - min_d), 0.0, 1.0)

	# Those Gaussians that were frustum culled or had a radius of 0 were not visible.
	# They will be excluded from value updates used in the splitting criteria.
	return {"render": rendered_image,
	"depth": disp,
	"alpha": alpha,
	"viewspace_points": screenspace_points,
	"visibility_filter" : radii > 0,
	"radii": radii,
	"scales": scales}