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""" |
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The renderer is a module that takes in rays, decides where to sample along each |
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ray, and computes pixel colors using the volume rendering equation. |
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""" |
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import torch |
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import torch.nn as nn |
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import torch.nn.functional as F |
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|
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from .ray_marcher import MipRayMarcher2 |
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from . import math_utils |
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|
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def generate_planes(): |
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""" |
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Defines planes by the three vectors that form the "axes" of the |
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plane. Should work with arbitrary number of planes and planes of |
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arbitrary orientation. |
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|
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Bugfix reference: https://github.com/NVlabs/eg3d/issues/67 |
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""" |
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return torch.tensor([[[1, 0, 0], |
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[0, 1, 0], |
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[0, 0, 1]], |
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[[1, 0, 0], |
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[0, 0, 1], |
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[0, 1, 0]], |
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[[0, 0, 1], |
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[0, 1, 0], |
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[1, 0, 0]]], dtype=torch.float32) |
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def project_onto_planes(planes, coordinates): |
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""" |
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Does a projection of a 3D point onto a batch of 2D planes, |
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returning 2D plane coordinates. |
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|
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Takes plane axes of shape n_planes, 3, 3 |
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# Takes coordinates of shape N, M, 3 |
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# returns projections of shape N*n_planes, M, 2 |
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""" |
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N, M, C = coordinates.shape |
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n_planes, _, _ = planes.shape |
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coordinates = coordinates.unsqueeze(1).expand(-1, n_planes, -1, -1).reshape(N*n_planes, M, 3) |
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inv_planes = torch.linalg.inv(planes).unsqueeze(0).expand(N, -1, -1, -1).reshape(N*n_planes, 3, 3) |
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coordinates = coordinates.to(inv_planes.device) |
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projections = torch.bmm(coordinates, inv_planes) |
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return projections[..., :2] |
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|
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def sample_from_planes(plane_axes, plane_features, coordinates, mode='bilinear', padding_mode='zeros', box_warp=None): |
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assert padding_mode == 'zeros' |
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N, n_planes, C, H, W = plane_features.shape |
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_, M, _ = coordinates.shape |
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plane_features = plane_features.view(N*n_planes, C, H, W) |
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coordinates = (2/box_warp) * coordinates |
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projected_coordinates = project_onto_planes(plane_axes, coordinates).unsqueeze(1) |
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output_features = torch.nn.functional.grid_sample(plane_features.float(), projected_coordinates.float(), mode=mode, padding_mode=padding_mode, align_corners=False).permute(0, 3, 2, 1).reshape(N, n_planes, M, C) |
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return output_features |
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|
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def sample_from_3dgrid(grid, coordinates): |
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""" |
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Expects coordinates in shape (batch_size, num_points_per_batch, 3) |
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Expects grid in shape (1, channels, H, W, D) |
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(Also works if grid has batch size) |
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Returns sampled features of shape (batch_size, num_points_per_batch, feature_channels) |
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""" |
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batch_size, n_coords, n_dims = coordinates.shape |
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sampled_features = torch.nn.functional.grid_sample(grid.expand(batch_size, -1, -1, -1, -1), |
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coordinates.reshape(batch_size, 1, 1, -1, n_dims), |
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mode='bilinear', padding_mode='zeros', align_corners=False) |
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N, C, H, W, D = sampled_features.shape |
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sampled_features = sampled_features.permute(0, 4, 3, 2, 1).reshape(N, H*W*D, C) |
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return sampled_features |
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|
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class ImportanceRenderer(torch.nn.Module): |
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""" |
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Modified original version to filter out-of-box samples as TensoRF does. |
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|
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Reference: |
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TensoRF: https://github.com/apchenstu/TensoRF/blob/main/models/tensorBase.py#L277 |
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""" |
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def __init__(self): |
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super().__init__() |
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self.activation_factory = self._build_activation_factory() |
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self.ray_marcher = MipRayMarcher2(self.activation_factory) |
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self.plane_axes = generate_planes() |
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|
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def _build_activation_factory(self): |
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def activation_factory(options: dict): |
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if options['clamp_mode'] == 'softplus': |
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return lambda x: F.softplus(x - 1) |
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else: |
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assert False, "Renderer only supports `clamp_mode`=`softplus`!" |
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return activation_factory |
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|
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def _forward_pass(self, depths: torch.Tensor, ray_directions: torch.Tensor, ray_origins: torch.Tensor, |
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planes: torch.Tensor, decoder: nn.Module, rendering_options: dict): |
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""" |
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Additional filtering is applied to filter out-of-box samples. |
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Modifications made by Zexin He. |
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""" |
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batch_size, num_rays, samples_per_ray, _ = depths.shape |
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device = planes.device |
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depths = depths.to(device) |
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ray_directions = ray_directions.to(device) |
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ray_origins = ray_origins.to(device) |
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|
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sample_directions = ray_directions.unsqueeze(-2).expand(-1, -1, samples_per_ray, -1).reshape(batch_size, -1, 3) |
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sample_coordinates = (ray_origins.unsqueeze(-2) + depths * ray_directions.unsqueeze(-2)).reshape(batch_size, -1, 3) |
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mask_inbox = \ |
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(rendering_options['sampler_bbox_min'] <= sample_coordinates) & \ |
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(sample_coordinates <= rendering_options['sampler_bbox_max']) |
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mask_inbox = mask_inbox.all(-1) |
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_out = self.run_model(planes, decoder, sample_coordinates, sample_directions, rendering_options) |
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SAFE_GUARD = 3 |
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DATA_TYPE = _out['sigma'].dtype |
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colors_pass = torch.zeros(batch_size, num_rays * samples_per_ray, 3, device=device, dtype=DATA_TYPE) |
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densities_pass = torch.nan_to_num(torch.full((batch_size, num_rays * samples_per_ray, 1), -float('inf'), device=device, dtype=DATA_TYPE)) / SAFE_GUARD |
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colors_pass[mask_inbox], densities_pass[mask_inbox] = _out['rgb'][mask_inbox], _out['sigma'][mask_inbox] |
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colors_pass = colors_pass.reshape(batch_size, num_rays, samples_per_ray, colors_pass.shape[-1]) |
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densities_pass = densities_pass.reshape(batch_size, num_rays, samples_per_ray, densities_pass.shape[-1]) |
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return colors_pass, densities_pass |
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|
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def forward(self, planes, decoder, ray_origins, ray_directions, rendering_options): |
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if rendering_options['ray_start'] == rendering_options['ray_end'] == 'auto': |
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ray_start, ray_end = math_utils.get_ray_limits_box(ray_origins, ray_directions, box_side_length=rendering_options['box_warp']) |
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is_ray_valid = ray_end > ray_start |
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if torch.any(is_ray_valid).item(): |
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ray_start[~is_ray_valid] = ray_start[is_ray_valid].min() |
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ray_end[~is_ray_valid] = ray_start[is_ray_valid].max() |
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depths_coarse = self.sample_stratified(ray_origins, ray_start, ray_end, rendering_options['depth_resolution'], rendering_options['disparity_space_sampling']) |
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else: |
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depths_coarse = self.sample_stratified(ray_origins, rendering_options['ray_start'], rendering_options['ray_end'], rendering_options['depth_resolution'], rendering_options['disparity_space_sampling']) |
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depths_coarse = depths_coarse.to(planes.device) |
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colors_coarse, densities_coarse = self._forward_pass( |
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depths=depths_coarse, ray_directions=ray_directions, ray_origins=ray_origins, |
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planes=planes, decoder=decoder, rendering_options=rendering_options) |
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N_importance = rendering_options['depth_resolution_importance'] |
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if N_importance > 0: |
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_, _, weights = self.ray_marcher(colors_coarse, densities_coarse, depths_coarse, rendering_options) |
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depths_fine = self.sample_importance(depths_coarse, weights, N_importance) |
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colors_fine, densities_fine = self._forward_pass( |
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depths=depths_fine, ray_directions=ray_directions, ray_origins=ray_origins, |
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planes=planes, decoder=decoder, rendering_options=rendering_options) |
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|
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all_depths, all_colors, all_densities = self.unify_samples(depths_coarse, colors_coarse, densities_coarse, |
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depths_fine, colors_fine, densities_fine) |
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rgb_final, depth_final, weights = self.ray_marcher(all_colors, all_densities, all_depths, rendering_options) |
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else: |
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rgb_final, depth_final, weights = self.ray_marcher(colors_coarse, densities_coarse, depths_coarse, rendering_options) |
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return rgb_final, depth_final, weights.sum(2) |
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|
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def run_model(self, planes, decoder, sample_coordinates, sample_directions, options): |
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plane_axes = self.plane_axes.to(planes.device) |
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sampled_features = sample_from_planes(plane_axes, planes, sample_coordinates, padding_mode='zeros', box_warp=options['box_warp']) |
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out = decoder(sampled_features, sample_directions) |
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if options.get('density_noise', 0) > 0: |
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out['sigma'] += torch.randn_like(out['sigma']) * options['density_noise'] |
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return out |
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|
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def run_model_activated(self, planes, decoder, sample_coordinates, sample_directions, options): |
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out = self.run_model(planes, decoder, sample_coordinates, sample_directions, options) |
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out['sigma'] = self.activation_factory(options)(out['sigma']) |
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return out |
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|
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def sort_samples(self, all_depths, all_colors, all_densities): |
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_, indices = torch.sort(all_depths, dim=-2) |
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all_depths = torch.gather(all_depths, -2, indices) |
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all_colors = torch.gather(all_colors, -2, indices.expand(-1, -1, -1, all_colors.shape[-1])) |
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all_densities = torch.gather(all_densities, -2, indices.expand(-1, -1, -1, 1)) |
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return all_depths, all_colors, all_densities |
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|
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def unify_samples(self, depths1, colors1, densities1, depths2, colors2, densities2): |
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all_depths = torch.cat([depths1, depths2], dim = -2) |
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all_colors = torch.cat([colors1, colors2], dim = -2) |
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all_densities = torch.cat([densities1, densities2], dim = -2) |
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_, indices = torch.sort(all_depths, dim=-2) |
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all_depths = torch.gather(all_depths, -2, indices) |
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all_colors = torch.gather(all_colors, -2, indices.expand(-1, -1, -1, all_colors.shape[-1])) |
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all_densities = torch.gather(all_densities, -2, indices.expand(-1, -1, -1, 1)) |
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return all_depths, all_colors, all_densities |
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|
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def sample_stratified(self, ray_origins, ray_start, ray_end, depth_resolution, disparity_space_sampling=False): |
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""" |
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Return depths of approximately uniformly spaced samples along rays. |
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""" |
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N, M, _ = ray_origins.shape |
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if disparity_space_sampling: |
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depths_coarse = torch.linspace(0, |
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1, |
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depth_resolution, |
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device=ray_origins.device).reshape(1, 1, depth_resolution, 1).repeat(N, M, 1, 1) |
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depth_delta = 1/(depth_resolution - 1) |
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depths_coarse += torch.rand_like(depths_coarse) * depth_delta |
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depths_coarse = 1./(1./ray_start * (1. - depths_coarse) + 1./ray_end * depths_coarse) |
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else: |
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if type(ray_start) == torch.Tensor: |
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depths_coarse = math_utils.linspace(ray_start, ray_end, depth_resolution).permute(1,2,0,3) |
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depth_delta = (ray_end - ray_start) / (depth_resolution - 1) |
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depths_coarse += torch.rand_like(depths_coarse) * depth_delta[..., None] |
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else: |
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depths_coarse = torch.linspace(ray_start, ray_end, depth_resolution, device=ray_origins.device).reshape(1, 1, depth_resolution, 1).repeat(N, M, 1, 1) |
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depth_delta = (ray_end - ray_start)/(depth_resolution - 1) |
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depths_coarse += torch.rand_like(depths_coarse) * depth_delta |
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|
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return depths_coarse |
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|
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def sample_importance(self, z_vals, weights, N_importance): |
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""" |
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Return depths of importance sampled points along rays. See NeRF importance sampling for more. |
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""" |
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with torch.no_grad(): |
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batch_size, num_rays, samples_per_ray, _ = z_vals.shape |
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|
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z_vals = z_vals.reshape(batch_size * num_rays, samples_per_ray) |
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weights = weights.reshape(batch_size * num_rays, -1) |
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weights = torch.nn.functional.max_pool1d(weights.unsqueeze(1).float(), 2, 1, padding=1) |
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weights = torch.nn.functional.avg_pool1d(weights, 2, 1).squeeze() |
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weights = weights + 0.01 |
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|
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z_vals_mid = 0.5 * (z_vals[: ,:-1] + z_vals[: ,1:]) |
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importance_z_vals = self.sample_pdf(z_vals_mid, weights[:, 1:-1], |
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N_importance).detach().reshape(batch_size, num_rays, N_importance, 1) |
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return importance_z_vals |
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|
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def sample_pdf(self, bins, weights, N_importance, det=False, eps=1e-5): |
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""" |
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Sample @N_importance samples from @bins with distribution defined by @weights. |
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Inputs: |
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bins: (N_rays, N_samples_+1) where N_samples_ is "the number of coarse samples per ray - 2" |
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weights: (N_rays, N_samples_) |
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N_importance: the number of samples to draw from the distribution |
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det: deterministic or not |
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eps: a small number to prevent division by zero |
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Outputs: |
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samples: the sampled samples |
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""" |
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N_rays, N_samples_ = weights.shape |
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weights = weights + eps |
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pdf = weights / torch.sum(weights, -1, keepdim=True) |
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cdf = torch.cumsum(pdf, -1) |
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cdf = torch.cat([torch.zeros_like(cdf[: ,:1]), cdf], -1) |
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if det: |
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u = torch.linspace(0, 1, N_importance, device=bins.device) |
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u = u.expand(N_rays, N_importance) |
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else: |
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u = torch.rand(N_rays, N_importance, device=bins.device) |
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u = u.contiguous() |
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|
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inds = torch.searchsorted(cdf, u, right=True) |
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below = torch.clamp_min(inds-1, 0) |
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above = torch.clamp_max(inds, N_samples_) |
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inds_sampled = torch.stack([below, above], -1).view(N_rays, 2*N_importance) |
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cdf_g = torch.gather(cdf, 1, inds_sampled).view(N_rays, N_importance, 2) |
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bins_g = torch.gather(bins, 1, inds_sampled).view(N_rays, N_importance, 2) |
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denom = cdf_g[...,1]-cdf_g[...,0] |
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denom[denom<eps] = 1 |
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samples = bins_g[...,0] + (u-cdf_g[...,0])/denom * (bins_g[...,1]-bins_g[...,0]) |
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return samples |