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import torch
torch.autograd.set_detect_anomaly(True)
import torch.nn as nn
import torch.nn.functional as F
import numpy as np
# import kilonerf_cuda
import math
import ray_utils
# Misc
img2mse = lambda x, y : torch.mean((x - y) ** 2)
mse2psnr = lambda x : -10. * torch.log(x) / torch.log(torch.Tensor([10.]))
to8b = lambda x : (255*np.clip(x,0,1)).astype(np.uint8)
# Positional encoding (section 5.1)
class Embedder:
def __init__(self, **kwargs):
self.kwargs = kwargs
self.create_embedding_fn()
def create_embedding_fn(self):
embed_fns = []
d = self.kwargs['input_dims']
out_dim = 0
if self.kwargs['include_input']:
embed_fns.append(lambda x : x)
out_dim += d
max_freq = self.kwargs['max_freq_log2']
N_freqs = self.kwargs['num_freqs']
if self.kwargs['log_sampling']:
freq_bands = 2.**torch.linspace(0., max_freq, steps=N_freqs)
else:
freq_bands = torch.linspace(2.**0., 2.**max_freq, steps=N_freqs)
for freq in freq_bands:
for p_fn in self.kwargs['periodic_fns']:
embed_fns.append(lambda x, p_fn=p_fn, freq=freq : p_fn(x * freq))
out_dim += d
self.embed_fns = embed_fns
self.out_dim = out_dim
def embed(self, inputs):
return torch.cat([fn(inputs) for fn in self.embed_fns], -1)
def get_embedder(multires, i=0):
if i == -1:
return nn.Identity(), 3
embed_kwargs = {
'include_input' : True,
'input_dims' : 3,
'max_freq_log2' : multires-1,
'num_freqs' : multires,
'log_sampling' : True,
'periodic_fns' : [torch.sin, torch.cos],
}
embedder_obj = Embedder(**embed_kwargs)
embed = lambda x, eo=embedder_obj : eo.embed(x)
return embed, embedder_obj.out_dim
class DenseLayer(nn.Linear):
def __init__(self, in_dim: int, out_dim: int, activation: str = "relu", *args, **kwargs) -> None:
self.activation = activation
super().__init__(in_dim, out_dim, *args, **kwargs)
def reset_parameters(self) -> None:
torch.nn.init.xavier_uniform_(self.weight, gain=torch.nn.init.calculate_gain(self.activation))
if self.bias is not None:
torch.nn.init.zeros_(self.bias)
# Model
class NeRF(nn.Module):
def __init__(self, D=8, W=256, input_ch=3, input_ch_views=3, output_ch=4, skips=[4], use_viewdirs=False, direction_layer_size=None, use_initialization_fix=False):
"""
"""
super(NeRF, self).__init__()
self.D = D
self.W = W
self.input_ch = input_ch
self.input_ch_views = input_ch_views
self.skips = skips
self.use_viewdirs = use_viewdirs
self.use_initialization_fix = use_initialization_fix
if direction_layer_size is None:
direction_layer_size = W//2
def linear_layer(in_features, out_features, activation):
if self.use_initialization_fix:
return DenseLayer(in_features, out_features, activation=activation)
else:
return nn.Linear(in_features, out_features)
self.pts_linears = nn.ModuleList(
[linear_layer(input_ch, W, activation="relu")] + [linear_layer(W, W, activation="relu") if i not in self.skips else linear_layer(W + input_ch, W, activation="relu") for i in range(D-1)])
### Implementation according to the official code release (https://github.com/bmild/nerf/blob/master/run_nerf_helpers.py#L104-L105)
self.views_linears = nn.ModuleList([linear_layer(input_ch_views + W, direction_layer_size, activation="relu")])
### Implementation according to the paper
# self.views_linears = nn.ModuleList(
# [nn.Linear(input_ch_views + W, W//2)] + [nn.Linear(W//2, W//2) for i in range(D//2)])
if use_viewdirs:
self.feature_linear = linear_layer(W, W, activation="linear")
self.alpha_linear = linear_layer(W, 1, activation="linear")
self.rgb_linear = linear_layer(direction_layer_size, 3, activation="linear")
else:
self.output_linear = linear_layer(W, output_ch, activation="linear")
def forward(self, x):
input_pts, input_views = torch.split(x, [self.input_ch, self.input_ch_views], dim=-1)
h = input_pts
for i, l in enumerate(self.pts_linears):
h = self.pts_linears[i](h)
h = F.relu(h)
if i in self.skips:
h = torch.cat([input_pts, h], -1)
if self.use_viewdirs:
alpha = self.alpha_linear(h)
feature = self.feature_linear(h)
h = torch.cat([feature, input_views], -1)
for i, l in enumerate(self.views_linears):
h = self.views_linears[i](h)
h = F.relu(h)
rgb = self.rgb_linear(h)
outputs = torch.cat([rgb, alpha], -1)
else:
outputs = self.output_linear(h)
return outputs
def load_weights_from_keras(self, weights):
assert self.use_viewdirs, "Not implemented if use_viewdirs=False"
# Load pts_linears
for i in range(self.D):
idx_pts_linears = 2 * i
self.pts_linears[i].weight.data = torch.from_numpy(np.transpose(weights[idx_pts_linears]))
self.pts_linears[i].bias.data = torch.from_numpy(np.transpose(weights[idx_pts_linears+1]))
# Load feature_linear
idx_feature_linear = 2 * self.D
self.feature_linear.weight.data = torch.from_numpy(np.transpose(weights[idx_feature_linear]))
self.feature_linear.bias.data = torch.from_numpy(np.transpose(weights[idx_feature_linear+1]))
# Load views_linears
idx_views_linears = 2 * self.D + 2
self.views_linears[0].weight.data = torch.from_numpy(np.transpose(weights[idx_views_linears]))
self.views_linears[0].bias.data = torch.from_numpy(np.transpose(weights[idx_views_linears+1]))
# Load rgb_linear
idx_rbg_linear = 2 * self.D + 4
self.rgb_linear.weight.data = torch.from_numpy(np.transpose(weights[idx_rbg_linear]))
self.rgb_linear.bias.data = torch.from_numpy(np.transpose(weights[idx_rbg_linear+1]))
# Load alpha_linear
idx_alpha_linear = 2 * self.D + 6
self.alpha_linear.weight.data = torch.from_numpy(np.transpose(weights[idx_alpha_linear]))
self.alpha_linear.bias.data = torch.from_numpy(np.transpose(weights[idx_alpha_linear+1]))
class NeRF2(nn.Module):
def __init__(self, D=8, W=256, input_ch=3, input_ch_views=3, input_ch_lights=3, output_ch=4, skips=[4], use_viewdirs=False, use_lightdirs=False, direction_layer_size=None, use_initialization_fix=False):
"""
"""
super(NeRF2, self).__init__()
self.D = D
self.W = W
self.input_ch = input_ch
self.input_ch_views = input_ch_views
self.input_ch_lights = input_ch_lights
self.skips = skips
self.use_viewdirs = use_viewdirs
self.use_lightdirs = use_lightdirs
self.use_initialization_fix = use_initialization_fix
"""
if direction_layer_size is None:
direction_layer_size = W//2
def linear_layer(in_features, out_features, activation):
if self.use_initialization_fix:
return DenseLayer(in_features, out_features, activation=activation)
else:
return nn.Linear(in_features, out_features)
self.pts_linears = nn.ModuleList(
[linear_layer(input_ch, W, activation="relu")] + [linear_layer(W, W, activation="relu") if i not in self.skips else linear_layer(W + input_ch, W, activation="relu") for i in range(D-1)])
"""
self.pts_linears = nn.ModuleList(
[nn.Linear(input_ch, W)] + [nn.Linear(W, W) if i not in self.skips else nn.Linear(W + input_ch, W) for i in range(D-1)])
### Implementation according to the official code release (https://github.com/bmild/nerf/blob/master/run_nerf_helpers.py#L104-L105)
#self.views_linears = nn.ModuleList([linear_layer(input_ch_views + W, direction_layer_size, activation="relu")])
### Implementation according to the paper
# self.views_linears = nn.ModuleList(
# [nn.Linear(input_ch_views + W, W//2)] + [nn.Linear(W//2, W//2) for i in range(D//2)])
"""
if use_viewdirs:
self.feature_linear = linear_layer(W, W, activation="linear")
self.alpha_linear = linear_layer(W, 1, activation="linear")
self.rgb_linear = linear_layer(direction_layer_size, 3, activation="linear")
else:
self.output_linear = linear_layer(W, output_ch, activation="linear")
"""
if use_viewdirs and use_lightdirs:
self.bottleneck_linear = nn.Linear(W, W)
self.alpha_linear = nn.Linear(W, 1)
self.rgb_linear = nn.Linear(W//2, 3)
self.views_lights_linears = nn.ModuleList([nn.Linear(input_ch_views + input_ch_lights + W, W//2)])
elif use_viewdirs:
self.bottleneck_linear = nn.Linear(W, W)
self.alpha_linear = nn.Linear(W, 1)
self.rgb_linear = nn.Linear(W//2, 3)
self.views_lights_linears = nn.ModuleList([nn.Linear(input_ch_views + W, W//2)])
elif use_lightdirs:
self.bottleneck_linear = nn.Linear(W, W)
self.alpha_linear = nn.Linear(W, 1)
self.rgb_linear = nn.Linear(W//2, 3)
self.views_lights_linears = nn.ModuleList([nn.Linear(input_ch_lights + W, W//2)])
else:
self.output_linear = nn.Linear(W, output_ch)
def forward(self, x):
input_pts, input_views, input_lights = torch.split(x, [self.input_ch, self.input_ch_views, self.input_ch_lights], dim=-1)
outputs = input_pts
for i, l in enumerate(self.pts_linears):
outputs = self.pts_linears[i](outputs)
outputs = F.relu(outputs)
if i in self.skips:
outputs = torch.cat([input_pts, outputs], -1)
"""
if self.use_viewdirs:
alpha = self.alpha_linear(h)
feature = self.feature_linear(h)
h = torch.cat([feature, input_views], -1)
for i, l in enumerate(self.views_linears):
h = self.views_linears[i](h)
h = F.relu(h)
rgb = self.rgb_linear(h)
outputs = torch.cat([rgb, alpha], -1)
else:
outputs = self.output_linear(h)
"""
if self.use_viewdirs or self.use_lightdirs:
alpha = self.alpha_linear(outputs)
bottleneck = self.bottleneck_linear(outputs)
inputs_dirs = bottleneck
if self.use_viewdirs:
inputs_dirs = torch.cat([inputs_dirs, input_views], -1) # concat viewdirs
if self.use_lightdirs:
inputs_dirs = torch.cat([inputs_dirs, input_lights], -1) # concat lightdirs
outputs = inputs_dirs
for i, l in enumerate(self.views_lights_linears):
outputs = self.views_lights_linears[i](outputs)
outputs = F.relu(outputs)
outputs = self.rgb_linear(outputs)
outputs = torch.cat([outputs, alpha], -1)
else:
outputs = self.output_linear(outputs)
return outputs
"""
def load_weights_from_keras(self, weights):
assert self.use_viewdirs, "Not implemented if use_viewdirs=False"
# Load pts_linears
for i in range(self.D):
idx_pts_linears = 2 * i
self.pts_linears[i].weight.data = torch.from_numpy(np.transpose(weights[idx_pts_linears]))
self.pts_linears[i].bias.data = torch.from_numpy(np.transpose(weights[idx_pts_linears+1]))
# Load feature_linear
idx_feature_linear = 2 * self.D
self.feature_linear.weight.data = torch.from_numpy(np.transpose(weights[idx_feature_linear]))
self.feature_linear.bias.data = torch.from_numpy(np.transpose(weights[idx_feature_linear+1]))
# Load views_linears
idx_views_linears = 2 * self.D + 2
self.views_linears[0].weight.data = torch.from_numpy(np.transpose(weights[idx_views_linears]))
self.views_linears[0].bias.data = torch.from_numpy(np.transpose(weights[idx_views_linears+1]))
# Load rgb_linear
idx_rbg_linear = 2 * self.D + 4
self.rgb_linear.weight.data = torch.from_numpy(np.transpose(weights[idx_rbg_linear]))
self.rgb_linear.bias.data = torch.from_numpy(np.transpose(weights[idx_rbg_linear+1]))
# Load alpha_linear
idx_alpha_linear = 2 * self.D + 6
self.alpha_linear.weight.data = torch.from_numpy(np.transpose(weights[idx_alpha_linear]))
self.alpha_linear.bias.data = torch.from_numpy(np.transpose(weights[idx_alpha_linear+1]))
"""
class CoarseAndFine(nn.Module):
def __init__(self, model_coarse, model_fine) :
super(CoarseAndFine, self).__init__()
self.model_coarse = model_coarse
self.model_fine = model_fine
def replace_transparency_by_background_color(acc_map, background_color=None):
res = 1. - acc_map[...,None]
if background_color is not None:
res = res * background_color
return res
# Ray helpers
#def get_rays(H, W, focal, c2w):
def get_rays(intrinsics, c2w, img_id=0, expand_origin=True):
'''
root_num_blocks = 64 # => 4096 blocks
root_num_threads = 16 # => 256 threads per block
rays_d = kilonerf_cuda.get_rays_d(intrinsics.H, intrinsics.W, intrinsics.cx, intrinsics.cy, intrinsics.fx, intrinsics.fy, c2w[:3, :3].contiguous(), root_num_blocks, root_num_threads)
'''
i, j = torch.meshgrid(torch.linspace(0, intrinsics.W-1, intrinsics.W), torch.linspace(0, intrinsics.H-1, intrinsics.H)) # pytorch's meshgrid has indexing='ij'
i = i.t()
j = j.t()
dirs = torch.stack([(i - intrinsics.cx) / intrinsics.fx, -(j - intrinsics.cy) / intrinsics.fy, -torch.ones_like(i)], -1)
# Rotate ray directions from camera frame to the world frame
rays_d = torch.sum(dirs[..., np.newaxis, :] * c2w[:3,:3], -1) # dot product, equals to: [c2w.dot(dir) for dir in dirs]
# Translate camera frame's origin to the world frame. It is the origin of all rays.
rays_o = c2w[:3,-1].expand(rays_d.shape)
if expand_origin:
rays_o = rays_o.expand(rays_d.shape)
else:
rays_o = rays_o.contiguous()
rays_i = torch.full(rays_d.size(), img_id).float()
return rays_o, rays_d, rays_i
#def get_rays_np(H, W, focal, c2w):
def get_rays_np(intrinsics, c2w):
W, H = intrinsics.W, intrinsics.H
i, j = np.meshgrid(np.arange(W, dtype=np.float32), np.arange(H, dtype=np.float32), indexing='xy')
dirs = np.stack([(i - intrinsics.cx) / intrinsics.fx, -(j - intrinsics.cy) / intrinsics.fy, -np.ones_like(i)], -1)
# Rotate ray directions from camera frame to the world frame
rays_d = np.sum(dirs[..., np.newaxis, :] * c2w[:3,:3], -1) # dot product, equals to: [c2w.dot(dir) for dir in dirs]
# Translate camera frame's origin to the world frame. It is the origin of all rays.
rays_o = np.broadcast_to(c2w[:3,-1], np.shape(rays_d))
return rays_o, rays_d
def ndc_rays(H, W, focal, near, rays_o, rays_d):
# Shift ray origins to near plane
t = -(near + rays_o[...,2]) / rays_d[...,2]
rays_o = rays_o + t[...,None] * rays_d
# Projection
o0 = -1./(W/(2.*focal)) * rays_o[...,0] / rays_o[...,2]
o1 = -1./(H/(2.*focal)) * rays_o[...,1] / rays_o[...,2]
o2 = 1. + 2. * near / rays_o[...,2]
d0 = -1./(W/(2.*focal)) * (rays_d[...,0]/rays_d[...,2] - rays_o[...,0]/rays_o[...,2])
d1 = -1./(H/(2.*focal)) * (rays_d[...,1]/rays_d[...,2] - rays_o[...,1]/rays_o[...,2])
d2 = -2. * near / rays_o[...,2]
rays_o = torch.stack([o0,o1,o2], -1)
rays_d = torch.stack([d0,d1,d2], -1)
return rays_o, rays_d
# Hierarchical sampling (section 5.2)
def sample_pdf(bins, weights, N_samples, det=False, pytest=False):
# Get pdf
weights = weights + 1e-5 # prevent nans
pdf = weights / torch.sum(weights, -1, keepdim=True)
cdf = torch.cumsum(pdf, -1)
cdf = torch.cat([torch.zeros_like(cdf[...,:1]), cdf], -1) # (batch, len(bins))
# Take uniform samples
if det:
u = torch.linspace(0., 1., steps=N_samples)
u = u.expand(list(cdf.shape[:-1]) + [N_samples])
else:
u = torch.rand(list(cdf.shape[:-1]) + [N_samples])
# Pytest, overwrite u with numpy's fixed random numbers
if pytest:
np.random.seed(0)
new_shape = list(cdf.shape[:-1]) + [N_samples]
if det:
u = np.linspace(0., 1., N_samples)
u = np.broadcast_to(u, new_shape)
else:
u = np.random.rand(*new_shape)
u = torch.Tensor(u)
# Invert CDF
u = u.contiguous()
inds = torch.searchsorted(cdf, u, right=True)
below = torch.max(torch.zeros_like(inds-1), inds-1)
above = torch.min((cdf.shape[-1]-1) * torch.ones_like(inds), inds)
inds_g = torch.stack([below, above], -1) # (batch, N_samples, 2)
# cdf_g = tf.gather(cdf, inds_g, axis=-1, batch_dims=len(inds_g.shape)-2)
# bins_g = tf.gather(bins, inds_g, axis=-1, batch_dims=len(inds_g.shape)-2)
matched_shape = [inds_g.shape[0], inds_g.shape[1], cdf.shape[-1]]
cdf_g = torch.gather(cdf.unsqueeze(1).expand(matched_shape), 2, inds_g)
bins_g = torch.gather(bins.unsqueeze(1).expand(matched_shape), 2, inds_g)
denom = (cdf_g[...,1]-cdf_g[...,0])
denom = torch.where(denom<1e-5, torch.ones_like(denom), denom)
t = (u-cdf_g[...,0])/denom
samples = bins_g[...,0] + t * (bins_g[...,1]-bins_g[...,0])
return samples
class ChainEmbeddingAndModel(nn.Module):
def __init__(self, model, embed_fn, embeddirs_fn, embedlights_fn):
super(ChainEmbeddingAndModel, self).__init__()
self.model = model
self.embed_fn = embed_fn
self.embeddirs_fn = embeddirs_fn
self.embedlights_fn = embedlights_fn
def forward(self, points_and_dirs):
embedded_points = self.embed_fn(points_and_dirs[:, :3])
if self.embeddirs_fn is not None and self.embedlights_fn is not None:
embedded_dirs = self.embeddirs_fn(points_and_dirs[:, 3:6])
embedded_lights = self.embedlights_fn(points_and_dirs[:, 6:])
embedded_points_and_dirs_and_lights = torch.cat([embedded_points, embedded_dirs, embedded_lights], -1)
return self.model(embedded_points_and_dirs_and_lights)
else:
return self.model(embedded_points)
def lookat(look_from, look_to, tmp = np.asarray([0., 0., 1.])):
forward = look_from - look_to
forward = forward / np.linalg.norm(forward)
right = np.cross(tmp, forward)
right = right / np.linalg.norm(right) # TODO: handle np.linalg.norm(right) == 0
up = np.cross(forward, right)
c2w_T = np.zeros((4,4))
c2w_T[0,0:3] = right
c2w_T[1,0:3] = up
c2w_T[2,0:3] = forward
c2w_T[3,0:3] = look_from
c2w_T[3,3] = 1
return c2w_T.T
class OrbitCamera:
def __init__(self, center, radius, inclination, azimuth, device):
self.center = center
self.radius = radius
self.inclination = inclination
self.azimuth = azimuth
self.device = device
self.compute_c2w()
def zoom(self, delta):
self.radius += delta
self.compute_c2w()
def pan(self, delta_x, delta_y):
c2w_T = self.c2w.cpu().numpy().T
right = c2w_T[0,0:3]
up = c2w_T[1,0:3]
self.center += delta_x * right
self.center += delta_y * up
self.compute_c2w()
def rotate(self, delta_x, delta_y):
self.azimuth += delta_x
self.inclination += delta_y
eps = 0.001
self.inclination = min(max(eps, self.inclination), math.pi - eps)
self.compute_c2w()
def compute_c2w(self):
offset = np.asarray([self.radius * math.cos(self.azimuth) * math.sin(self.inclination),
self.radius * math.sin(self.azimuth) * math.sin(self.inclination),
self.radius * math.cos(self.inclination)])
look_from = self.center + offset
look_to = self.center
self.c2w = torch.tensor(lookat(look_from, look_to), dtype=torch.float, device=self.device)
def get_dirs(ray_batch, pts, metadata, use_viewdirs, use_lightdirs, lightdirs_method):
"""Get ray directions.
Args:
ray_batch: [R, M] float tensor. All information necessary for sampling along a
ray, including: ray origin, ray direction, min dist, max dist, and
unit-magnitude viewing direction, all in object coordinate frame.
pts: [R, S, 3] float tensor. Sampled points along rays.
metadata: [N, 3] float tensor. Metadata about each image. Currently only light
position is provided.
use_viewdirs: Whether to use view directions.
use_lightdirs: Whether to use light directions.
lightdirs_method: Method for computing lightdirs.
"""
viewdirs, lightdirs = None, None
if use_viewdirs:
assert ray_batch.size()[-1] > 8
viewdirs = ray_batch[:, 8:11] # [R, 3]
viewdirs = torch.broadcast_to(viewdirs[:, None], pts.size()) # [R, S, 3]
if use_lightdirs:
# Use viewdirs as lightdirs.
if lightdirs_method == 'viewdirs':
assert viewdirs is not None, "viewdirs is None"
lightdirs = viewdirs # [R, S, 3]
# Compute lightdirs based on ray metadata or randomly sample directions.
else:
rays_i = ray_batch[:, -1:] # [R, 1]
lightdirs = ray_utils.get_lightdirs( # [R, S, 3]
lightdirs_method=lightdirs_method, num_rays=pts.size()[0],
num_samples=pts.size()[1], rays_i=rays_i, metadata=metadata,
normalize=False)
return viewdirs, lightdirs