Datasets:

KCBtheone
/

splatatlas-core

	import os
	import sys
	import random
	import torch
	import numpy as np
	import torch.nn.functional as F
	from argparse import ArgumentParser
	from core.registry import register_method
	from core.base_method import BaseMethod

	# [Isolation Step 1] 剔除所有路径污染
	sys.path = [p for p in sys.path if 'taming-3dgs' not in p]

	# [Isolation Step 2] 插入正确路径
	gsshader_root = os.path.abspath(os.path.join(os.path.dirname(__file__), '../../gsshader_official'))
	if gsshader_root not in sys.path:
	sys.path.insert(0, gsshader_root)

	# [Isolation Step 3] 强制清理模块缓存，防止重名污染
	for m in list(sys.modules.keys()):
	base_m = m.split('.')[0]
	if base_m in ["utils", "scene", "gaussian_renderer", "arguments"]:
	del sys.modules[m]

	from utils.loss_utils import l1_loss, ssim, predicted_normal_loss, delta_normal_loss, zero_one_loss
	from gaussian_renderer import render as native_render
	from scene import Scene, GaussianModel
	from arguments import ModelParams, PipelineParams, OptimizationParams

	@register_method("gsshader")
	class GSShaderWrapper(BaseMethod):
	def __init__(self, dataset_config, hyperparams):
	self.parser = ArgumentParser()
	self.lp = ModelParams(self.parser)
	self.op = OptimizationParams(self.parser)
	self.pp = PipelineParams(self.parser)
	self.args, _ = self.parser.parse_known_args([])

	self.args.source_path = dataset_config["source_path"]
	self.args.model_path = dataset_config["model_path"]
	self.args.eval = True
	self.args.resolution = dataset_config.get("resolution", 1)
	self.track_decoupling = hyperparams.get("track_decoupling", False)

	self.dataset = self.lp.extract(self.args)
	self.opt = self.op.extract(self.args)
	self.pipe = self.pp.extract(self.args)

	self.gaussians = GaussianModel(
	self.dataset.sh_degree,
	self.dataset.brdf_dim,
	self.dataset.brdf_mode,
	self.dataset.brdf_envmap_res
	)
	self.scene = Scene(self.dataset, self.gaussians)
	self.gaussians.training_setup(self.opt)

	bg_color = [1, 1, 1] if self.dataset.white_background else [0, 0, 0]
	self.background = torch.tensor(bg_color, dtype=torch.float32, device="cuda")
	self.viewpoint_stack = self.scene.getTrainCameras().copy()
	self.last_n_gaussians = len(self.gaussians.get_xyz)

	def train_iteration(self, step):
	self.gaussians.update_learning_rate(step)
	if step % 1000 == 0:
	self.gaussians.oneupSHdegree()

	if not self.viewpoint_stack:
	self.viewpoint_stack = self.scene.getTrainCameras().copy()

	viewpoint_cam = self.viewpoint_stack.pop(random.randint(0, len(self.viewpoint_stack) - 1))

	if self.pipe.brdf:
	self.gaussians.set_requires_grad("normal", state=step >= self.opt.normal_reg_from_iter)
	self.gaussians.set_requires_grad("normal2", state=step >= self.opt.normal_reg_from_iter)
	if self.gaussians.brdf_mode == "envmap":
	self.gaussians.brdf_mlp.build_mips()

	render_pkg = native_render(viewpoint_cam, self.gaussians, self.pipe, self.background, debug=False)
	image = render_pkg["render"]
	viewspace_point_tensor = render_pkg["viewspace_points"]
	visibility_filter = render_pkg["visibility_filter"]
	radii = render_pkg["radii"]

	gt_image = viewpoint_cam.original_image.cuda()
	Ll1 = l1_loss(image, gt_image)
	loss_target = (1.0 - self.opt.lambda_dssim) * Ll1 + self.opt.lambda_dssim * (1.0 - ssim(image, gt_image))

	loss_parasitic = torch.tensor(0.0, device="cuda")
	if self.pipe.brdf and step > self.opt.normal_reg_from_iter:
	if step < self.opt.normal_reg_util_iter:
	loss_parasitic += self.opt.lambda_predicted_normal * predicted_normal_loss(render_pkg["normal"], render_pkg["normal_ref"], render_pkg["alpha"])
	loss_parasitic += self.opt.lambda_zero_one * zero_one_loss(render_pkg["alpha"])
	if "delta_normal_norm" in render_pkg.keys():
	loss_parasitic += self.opt.lambda_delta_reg * delta_normal_loss(render_pkg["delta_normal_norm"], render_pkg["alpha"])

	loss = loss_target + loss_parasitic

	grad_cos_sim = 0.0
	parasitic_ratio = 0.0

	if self.track_decoupling and step % 100 == 0 and loss_parasitic.item() > 0:
	self.gaussians.optimizer.zero_grad(set_to_none=True)
	loss_target.backward(retain_graph=True)
	grad_target = self.gaussians._xyz.grad.clone() if self.gaussians._xyz.grad is not None else torch.zeros_like(self.gaussians._xyz)

	self.gaussians.optimizer.zero_grad(set_to_none=True)
	loss_parasitic.backward(retain_graph=True)
	grad_parasitic = self.gaussians._xyz.grad.clone() if self.gaussians._xyz.grad is not None else torch.zeros_like(self.gaussians._xyz)

	valid_mask = (torch.norm(grad_target, dim=1) > 0) & (torch.norm(grad_parasitic, dim=1) > 0)
	if valid_mask.any():
	grad_cos_sim = float(F.cosine_similarity(grad_target[valid_mask], grad_parasitic[valid_mask], dim=1).mean())
	parasitic_ratio = float(torch.norm(grad_parasitic, dim=1).mean() / (torch.norm(grad_target, dim=1).mean() + 1e-7))

	self.gaussians.optimizer.zero_grad(set_to_none=True)
	loss.backward()
	else:
	loss.backward()

	with torch.no_grad():
	if step < self.opt.densify_until_iter:
	self.gaussians.max_radii2D[visibility_filter] = torch.max(self.gaussians.max_radii2D[visibility_filter], radii[visibility_filter])
	self.gaussians.add_densification_stats(viewspace_point_tensor, visibility_filter)

	if step > self.opt.densify_from_iter and step % self.opt.densification_interval == 0:
	size_threshold = 20 if step > self.opt.opacity_reset_interval else None
	self.gaussians.densify_and_prune(self.opt.densify_grad_threshold, 0.005, self.scene.cameras_extent, size_threshold)

	if step % self.opt.opacity_reset_interval == 0 or (self.dataset.white_background and step == self.opt.densify_from_iter):
	self.gaussians.reset_opacity()

	self.gaussians.optimizer.step()
	self.gaussians.optimizer.zero_grad(set_to_none=True)

	if self.pipe.brdf and self.pipe.brdf_mode == "envmap":
	self.gaussians.brdf_mlp.clamp_(min=0.0, max=1.0)

	num_gaussians = self.gaussians.get_xyz.shape[0]
	metrics = {
	"loss": float(loss),
	"loss_l1": float(loss_target),
	"loss_ssim": float(loss_parasitic),
	"num_gaussians": int(num_gaussians),
	"delta_N": int(num_gaussians - self.last_n_gaussians),
	"peak_vram_GB": float(torch.cuda.max_memory_allocated() / (1024 ** 3)),
	"grad_cos_sim": float(grad_cos_sim),
	"parasitic_ratio": float(parasitic_ratio)
	}
	self.last_n_gaussians = num_gaussians

	histograms = {}
	if step % 1000 == 0:
	histograms["opacity"] = torch.sigmoid(self.gaussians._opacity).clone().detach()
	scales = torch.exp(self.gaussians._scaling).clone().detach()
	histograms["scaling"] = scales
	scales_2d = scales[:, :2] if scales.shape[1] >= 2 else scales
	gamma = scales_2d.max(dim=-1)[0] / (scales_2d.min(dim=-1)[0] + 1e-7)
	histograms["anisotropy"] = gamma
	histograms["sh_dc_mag"] = self.gaussians._features_dc.detach().norm(dim=-1)

	return metrics, histograms

	def render(self, camera):
	with torch.no_grad():
	render_pkg = native_render(camera, self.gaussians, self.pipe, self.background, debug=False)
	return {"image": render_pkg["render"], "depth": render_pkg.get("depth", None)}

	def save(self, save_dir, step):
	self.scene.save(step)

	def load(self, model_path, iteration):
	self.gaussians.load_ply(os.path.join(model_path, 'point_cloud', f'iteration_{iteration}', 'point_cloud.ply'))

	def get_spatial_centers(self):
	return self.gaussians._xyz

	def compute_physical_metrics(self, cameras=None):
	metrics = {}
	with torch.no_grad():
	raw_scales = self.gaussians._scaling
	scales = torch.exp(raw_scales)
	scales_2d = scales[:, :2] if scales.dim() > 1 and scales.shape[1] >= 2 else scales.unsqueeze(-1).expand(-1, 2)

	max_S, _ = torch.max(scales_2d, dim=1)
	min_S, _ = torch.min(scales_2d, dim=1)
	gamma = max_S / (min_S + 1e-7)

	metrics["gamma_median"] = float(torch.median(gamma))
	metrics["gamma_90th_percentile"] = float(torch.quantile(gamma, 0.90))
	metrics["scale_mean"] = float(torch.mean(scales_2d))
	metrics["alpha_mean"] = float(torch.mean(torch.sigmoid(self.gaussians._opacity)))

	dc, rest = self.gaussians._features_dc, self.gaussians._features_rest
	if rest is not None and rest.shape[1] > 0:
	metrics["sh_energy_ratio"] = float(rest.norm(dim=-1).mean() / (dc.norm(dim=-1).mean() + 1e-7))

	if self.pipe.brdf:
	metrics["roughness_mean"] = float(torch.mean(torch.sigmoid(self.gaussians._roughness + self.gaussians.roughness_bias)))
	metrics["specular_mean"] = float(torch.mean(torch.sigmoid(self.gaussians._specular)))

	if cameras is not None and len(cameras) > 0:
	view_dirs = []
	for c in cameras:
	view_dirs.append(c.world_view_transform[:3, 2].tolist())
	view_dirs = F.normalize(torch.tensor(view_dirs, dtype=torch.float32, device="cuda"), dim=1)

	rots = F.normalize(self.gaussians._rotation.clone(), dim=1)
	w, x, y, z = rots.unbind(dim=-1)
	normals = F.normalize(torch.stack([2(xz + wy), 2(yz - wx), 1-2(xx + y*y)], dim=-1), dim=1)

	max_cos, _ = torch.max(torch.abs(torch.matmul(normals, view_dirs.T)), dim=1)
	metrics["billboard_bias_ratio"] = float((max_cos > 0.90).float().mean())

	return metrics

	def evaluate_spatial_field(self, query_points: torch.Tensor, cameras=None) -> torch.Tensor:
	with torch.no_grad():
	V = query_points.shape[0]
	densities = torch.zeros(V, device="cuda")
	xyz, opacities = self.gaussians._xyz, torch.sigmoid(self.gaussians._opacity).squeeze()
	scales = torch.exp(self.gaussians._scaling)
	sigma_sq = (scales[:, :2].max(dim=1)[0].pow(2)) if scales.shape[1] >= 2 else scales.squeeze().pow(2)

	N_gaussians = xyz.shape[0]
	chunk_size = max(1, 30_000_000 // (N_gaussians + 1))
	for i in range(0, V, chunk_size):
	end = min(i + chunk_size, V)
	dist_sq = torch.cdist(query_points[i:end], xyz, p=2).pow(2)
	weights = torch.exp(-0.5 * dist_sq / (sigma_sq.unsqueeze(0) + 1e-7))
	densities[i:end] = torch.sum(weights * opacities.unsqueeze(0), dim=1)
	return densities