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run_nerf.py
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run_nerf.py
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import os
os.environ['TF_FORCE_GPU_ALLOW_GROWTH'] = 'true'
import sys
import tensorflow as tf
import numpy as np
import imageio
import json
import random
import time
from run_nerf_helpers import *
from load_llff import load_llff_data
from load_deepvoxels import load_dv_data
from load_blender import load_blender_data
from tensorflow import keras
from tensorflow.keras import layers
tf.compat.v1.enable_eager_execution()
def batchify(fn, chunk):
"""Constructs a version of 'fn' that applies to smaller batches."""
if chunk is None:
return fn
def ret(inputs):
return tf.concat([fn(inputs[i:i+chunk]) for i in range(0, inputs.shape[0], chunk)], 0)
return ret
def run_network(inputs, viewdirs, fn, embed_fn, embeddirs_fn, netchunk=1024*64):
"""Prepares inputs and applies network 'fn'."""
inputs_flat = tf.reshape(inputs, [-1, inputs.shape[-1]])
embedded = embed_fn(inputs_flat)
if viewdirs is not None:
input_dirs = tf.broadcast_to(viewdirs[:, None], inputs.shape)
input_dirs_flat = tf.reshape(input_dirs, [-1, input_dirs.shape[-1]])
embedded_dirs = embeddirs_fn(input_dirs_flat)
embedded = tf.concat([embedded, embedded_dirs], -1)
#extractor = keras.Model(inputs=fn.inputs,
# outputs=fn.layers[15].output)
#temp = tf.reshape(embedded[0],[1,90])
#print(inputs_flat[0])
#print(input_dirs_flat[0])
#print(extractor.predict(temp))
#print( fn.layers[2].weights[0] )
#exit(0)
from inf import predict
print(predict(embedded[0:1].numpy(),2))
# TODO: change batchify with self defined c++ network
outputs_flat = batchify(fn, netchunk)(embedded)
outputs = tf.reshape(outputs_flat, list(
inputs.shape[:-1]) + [outputs_flat.shape[-1]])
return outputs
def render_rays(ray_batch,
network_fn,
network_query_fn,
N_samples,
retraw=False,
lindisp=False,
perturb=0.,
N_importance=0,
network_fine=None,
white_bkgd=False,
raw_noise_std=0.,
verbose=False):
"""Volumetric rendering.
Args:
ray_batch: array of shape [batch_size, ...]. All information necessary
for sampling along a ray, including: ray origin, ray direction, min
dist, max dist, and unit-magnitude viewing direction.
network_fn: function. Model for predicting RGB and density at each point
in space.ft_path
network_query_fn: function used for passing queries to network_fn.
N_samples: int. Number of different times to sample along each ray.
retraw: bool. If True, include model's raw, unprocessed predictions.
lindisp: bool. If True, sample linearly in inverse depth rather than in depth.
perturb: float, 0 or 1. If non-zero, each ray is sampled at stratified
random points in time.
N_importance: int. Number of additional times to sample along each ray.
These samples are only passed to network_fine.
network_fine: "fine" network with same spec as network_fn.
white_bkgd: bool. If True, assume a white background.
raw_noise_std: ...
verbose: bool. If True, print more debugging info.
Returns:
rgb_map: [num_rays, 3]. Estimated RGB color of a ray. Comes from fine model.
disp_map: [num_rays]. Disparity map. 1 / depth.
acc_map: [num_rays]. Accumulated opacity along each ray. Comes from fine model.
raw: [num_rays, num_samples, 4]. Raw predictions from model.
rgb0: See rgb_map. Output for coarse model.
disp0: See disp_map. Output for coarse model.
acc0: See acc_map. Output for coarse model.
z_std: [num_rays]. Standard deviation of distances along ray for each
sample.
"""
def raw2outputs(raw, z_vals, rays_d):
"""Transforms model's predictions to semantically meaningful values.
Args:
raw: [num_rays, num_samples along ray, 4]. Prediction from model.
z_vals: [num_rays, num_samples along ray]. Integration time.
rays_d: [num_rays, 3]. Direction of each ray.
Returns:
rgb_map: [num_rays, 3]. Estimated RGB color of a ray.
disp_map: [num_rays]. Disparity map. Inverse of depth map.
acc_map: [num_rays]. Sum of weights along each ray.
weights: [num_rays, num_samples]. Weights assigned to each sampled color.
depth_map: [num_rays]. Estimated distance to object.
"""
# Function for computing density from model prediction. This value is
# strictly between [0, 1].
def raw2alpha(raw, dists, act_fn=tf.nn.relu): return 1.0 - \
tf.exp(-act_fn(raw) * dists)
# Compute 'distance' (in time) between each integration time along a ray.
dists = z_vals[..., 1:] - z_vals[..., :-1]
# The 'distance' from the last integration time is infinity.
dists = tf.concat(
[dists, tf.broadcast_to([1e10], dists[..., :1].shape)],
axis=-1) # [N_rays, N_samples]
# Multiply each distance by the norm of its corresponding direction ray
# to convert to real world distance (accounts for non-unit directions).
dists = dists * tf.linalg.norm(rays_d[..., None, :], axis=-1)
# Extract RGB of each sample position along each ray.
rgb = tf.math.sigmoid(raw[..., :3]) # [N_rays, N_samples, 3]
# Add noise to model's predictions for density. Can be used to
# regularize network during training (prevents floater artifacts).
noise = 0.
if raw_noise_std > 0.:
noise = tf.random.normal(raw[..., 3].shape) * raw_noise_std
# Predict density of each sample along each ray. Higher values imply
# higher likelihood of being absorbed at this point.
alpha = raw2alpha(raw[..., 3] + noise, dists) # [N_rays, N_samples]
# Compute weight for RGB of each sample along each ray. A cumprod() is
# used to express the idea of the ray not having reflected up to this
# sample yet.
# [N_rays, N_samples]
weights = alpha * \
tf.math.cumprod(1.-alpha + 1e-10, axis=-1, exclusive=True)
# Computed weighted color of each sample along each ray.
rgb_map = tf.reduce_sum(
weights[..., None] * rgb, axis=-2) # [N_rays, 3]
# Estimated depth map is expected distance.
depth_map = tf.reduce_sum(weights * z_vals, axis=-1)
# Disparity map is inverse depth.
disp_map = 1./tf.maximum(1e-10, depth_map /
tf.reduce_sum(weights, axis=-1))
# Sum of weights along each ray. This value is in [0, 1] up to numerical error.
acc_map = tf.reduce_sum(weights, -1)
# To composite onto a white background, use the accumulated alpha map.
if white_bkgd:
rgb_map = rgb_map + (1.-acc_map[..., None])
return rgb_map, disp_map, acc_map, weights, depth_map
###############################
# batch size
N_rays = ray_batch.shape[0]
# Extract ray origin, direction.
rays_o, rays_d = ray_batch[:, 0:3], ray_batch[:, 3:6] # [N_rays, 3] each
# Extract unit-normalized viewing direction.
viewdirs = ray_batch[:, -3:] if ray_batch.shape[-1] > 8 else None
# Extract lower, upper bound for ray distance.
bounds = tf.reshape(ray_batch[..., 6:8], [-1, 1, 2])
near, far = bounds[..., 0], bounds[..., 1] # [-1,1]
# Decide where to sample along each ray. Under the logic, all rays will be sampled at
# the same times.
t_vals = tf.linspace(0., 1., N_samples)
if not lindisp:
# Space integration times linearly between 'near' and 'far'. Same
# integration points will be used for all rays.
z_vals = near * (1.-t_vals) + far * (t_vals)
else:
# Sample linearly in inverse depth (disparity).
z_vals = 1./(1./near * (1.-t_vals) + 1./far * (t_vals))
z_vals = tf.broadcast_to(z_vals, [N_rays, N_samples])
# Perturb sampling time along each ray.
if perturb > 0.:
# get intervals between samples
mids = .5 * (z_vals[..., 1:] + z_vals[..., :-1])
upper = tf.concat([mids, z_vals[..., -1:]], -1)
lower = tf.concat([z_vals[..., :1], mids], -1)
# stratified samples in those intervals
t_rand = tf.random.uniform(z_vals.shape)
z_vals = lower + (upper - lower) * t_rand
# Points in space to evaluate model at.
pts = rays_o[..., None, :] + rays_d[..., None, :] * \
z_vals[..., :, None] # [N_rays, N_samples, 3]
# Evaluate model at each point.
raw = network_query_fn(pts, viewdirs, network_fn) # [N_rays, N_samples, 4] # TODO: modify it to support c++ backend
rgb_map, disp_map, acc_map, weights, depth_map = raw2outputs(
raw, z_vals, rays_d)
if N_importance > 0:
rgb_map_0, disp_map_0, acc_map_0 = rgb_map, disp_map, acc_map
# Obtain additional integration times to evaluate based on the weights
# assigned to colors in the coarse model.
z_vals_mid = .5 * (z_vals[..., 1:] + z_vals[..., :-1])
z_samples = sample_pdf(
z_vals_mid, weights[..., 1:-1], N_importance, det=(perturb == 0.))
z_samples = tf.stop_gradient(z_samples)
# Obtain all points to evaluate color, density at.
z_vals = tf.sort(tf.concat([z_vals, z_samples], -1), -1)
pts = rays_o[..., None, :] + rays_d[..., None, :] * \
z_vals[..., :, None] # [N_rays, N_samples + N_importance, 3]
# Make predictions with network_fine.
run_fn = network_fn if network_fine is None else network_fine
raw = network_query_fn(pts, viewdirs, run_fn)
rgb_map, disp_map, acc_map, weights, depth_map = raw2outputs(
raw, z_vals, rays_d)
ret = {'rgb_map': rgb_map, 'disp_map': disp_map, 'acc_map': acc_map}
if retraw:
ret['raw'] = raw
if N_importance > 0:
ret['rgb0'] = rgb_map_0
ret['disp0'] = disp_map_0
ret['acc0'] = acc_map_0
ret['z_std'] = tf.math.reduce_std(z_samples, -1) # [N_rays]
for k in ret:
tf.debugging.check_numerics(ret[k], 'output {}'.format(k))
return ret
def batchify_rays(rays_flat, chunk=1024*32, **kwargs):
"""Render rays in smaller minibatches to avoid OOM."""
all_ret = {}
for i in range(0, rays_flat.shape[0], chunk):
ret = render_rays(rays_flat[i:i+chunk], **kwargs)
for k in ret:
if k not in all_ret:
all_ret[k] = []
all_ret[k].append(ret[k])
all_ret = {k: tf.concat(all_ret[k], 0) for k in all_ret}
return all_ret
def render(H, W, focal,
chunk=1024*32, rays=None, c2w=None, ndc=True,
near=0., far=1.,
use_viewdirs=False, c2w_staticcam=None,
**kwargs):
"""Render rays
Args:
H: int. Height of image in pixels.
W: int. Width of image in pixels.
focal: float. Focal length of pinhole camera.
chunk: int. Maximum number of rays to process simultaneously. Used to
control maximum memory usage. Does not affect final results.
rays: array of shape [2, batch_size, 3]. Ray origin and direction for
each example in batch.
c2w: array of shape [3, 4]. Camera-to-world transformation matrix.
ndc: bool. If True, represent ray origin, direction in NDC coordinates.
near: float or array of shape [batch_size]. Nearest distance for a ray.
far: float or array of shape [batch_size]. Farthest distance for a ray.
use_viewdirs: bool. If True, use viewing direction of a point in space in model.
c2w_staticcam: array of shape [3, 4]. If not None, use this transformation matrix for
camera while using other c2w argument for viewing directions.
Returns:
rgb_map: [batch_size, 3]. Predicted RGB values for rays.
disp_map: [batch_size]. Disparity map. Inverse of depth.
acc_map: [batch_size]. Accumulated opacity (alpha) along a ray.
extras: dict with everything returned by render_rays().
"""
if c2w is not None:
# special case to render full image
rays_o, rays_d = get_rays(H, W, focal, c2w)
else:
# use provided ray batch
rays_o, rays_d = rays
if use_viewdirs:
# provide ray directions as input
viewdirs = rays_d
if c2w_staticcam is not None:
# special case to visualize effect of viewdirs
rays_o, rays_d = get_rays(H, W, focal, c2w_staticcam)
# Make all directions unit magnitude.
# shape: [batch_size, 3]
viewdirs = viewdirs / tf.linalg.norm(viewdirs, axis=-1, keepdims=True)
viewdirs = tf.cast(tf.reshape(viewdirs, [-1, 3]), dtype=tf.float32)
sh = rays_d.shape # [..., 3]
if ndc:
# for forward facing scenes
rays_o, rays_d = ndc_rays(
H, W, focal, tf.cast(1., tf.float32), rays_o, rays_d)
# Create ray batch
rays_o = tf.cast(tf.reshape(rays_o, [-1, 3]), dtype=tf.float32)
rays_d = tf.cast(tf.reshape(rays_d, [-1, 3]), dtype=tf.float32)
near, far = near * \
tf.ones_like(rays_d[..., :1]), far * tf.ones_like(rays_d[..., :1])
# (ray origin, ray direction, min dist, max dist) for each ray
rays = tf.concat([rays_o, rays_d, near, far], axis=-1)
if use_viewdirs:
# (ray origin, ray direction, min dist, max dist, normalized viewing direction)
rays = tf.concat([rays, viewdirs], axis=-1)
# Render and reshape
all_ret = batchify_rays(rays, chunk, **kwargs)
for k in all_ret:
k_sh = list(sh[:-1]) + list(all_ret[k].shape[1:])
all_ret[k] = tf.reshape(all_ret[k], k_sh)
k_extract = ['rgb_map', 'disp_map', 'acc_map']
ret_list = [all_ret[k] for k in k_extract]
ret_dict = {k: all_ret[k] for k in all_ret if k not in k_extract}
return ret_list + [ret_dict]
def render_path(render_poses, hwf, chunk, render_kwargs, gt_imgs=None, savedir=None, render_factor=0):
H, W, focal = hwf
if render_factor != 0:
# Render downsampled for speed
H = H//render_factor
W = W//render_factor
focal = focal/render_factor
rgbs = []
disps = []
t = time.time()
for i, c2w in enumerate(render_poses):
print(i, time.time() - t)
t = time.time()
rgb, disp, acc, _ = render(
H, W, focal, chunk=chunk, c2w=c2w[:3, :4], **render_kwargs)
rgbs.append(rgb.numpy())
disps.append(disp.numpy())
if i == 0:
print(rgb.shape, disp.shape)
if gt_imgs is not None and render_factor == 0:
p = -10. * np.log10(np.mean(np.square(rgb - gt_imgs[i])))
print(p)
if savedir is not None:
rgb8 = to8b(rgbs[-1])
filename = os.path.join(savedir, '{:03d}.png'.format(i))
imageio.imwrite(filename, rgb8)
rgbs = np.stack(rgbs, 0)
disps = np.stack(disps, 0)
return rgbs, disps
def create_nerf(args):
"""Instantiate NeRF's MLP model."""
embed_fn, input_ch = get_embedder(args.multires, args.i_embed)
input_ch_views = 0
embeddirs_fn = None
if args.use_viewdirs:
embeddirs_fn, input_ch_views = get_embedder(
args.multires_views, args.i_embed)
output_ch = 4
skips = [4]
model = init_nerf_model(
D=args.netdepth, W=args.netwidth,
input_ch=input_ch, output_ch=output_ch, skips=skips,
input_ch_views=input_ch_views, use_viewdirs=args.use_viewdirs)
grad_vars = model.trainable_variables
models = {'model': model}
model_fine = None
if args.N_importance > 0:
model_fine = init_nerf_model(
D=args.netdepth_fine, W=args.netwidth_fine,
input_ch=input_ch, output_ch=output_ch, skips=skips,
input_ch_views=input_ch_views, use_viewdirs=args.use_viewdirs)
grad_vars += model_fine.trainable_variables
models['model_fine'] = model_fine
def network_query_fn(inputs, viewdirs, network_fn): return run_network(
inputs, viewdirs, network_fn,
embed_fn=embed_fn,
embeddirs_fn=embeddirs_fn,
netchunk=args.netchunk)
render_kwargs_train = {
'network_query_fn': network_query_fn,
'perturb': args.perturb,
'N_importance': args.N_importance,
'network_fine': model_fine,
'N_samples': args.N_samples,
'network_fn': model,
'use_viewdirs': args.use_viewdirs,
'white_bkgd': args.white_bkgd,
'raw_noise_std': args.raw_noise_std,
}
# NDC only good for LLFF-style forward facing data
if args.dataset_type != 'llff' or args.no_ndc:
print('Not ndc!')
render_kwargs_train['ndc'] = False
render_kwargs_train['lindisp'] = args.lindisp
render_kwargs_test = {
k: render_kwargs_train[k] for k in render_kwargs_train}
render_kwargs_test['perturb'] = False
render_kwargs_test['raw_noise_std'] = 0.
start = 0
basedir = args.basedir
expname = args.expname
if args.ft_path is not None and args.ft_path != 'None':
ckpts = [args.ft_path]
else:
ckpts = [os.path.join(basedir, expname, f) for f in sorted(os.listdir(os.path.join(basedir, expname))) if
('model_' in f and 'fine' not in f and 'optimizer' not in f)]
print('Found ckpts', ckpts)
if len(ckpts) > 0 and not args.no_reload:
ft_weights = ckpts[-1]
print('Reloading from', ft_weights)
model.set_weights(np.load(ft_weights, allow_pickle=True))
start = int(ft_weights[-10:-4]) + 1
print('Resetting step to', start)
if model_fine is not None:
ft_weights_fine = '{}_fine_{}'.format(
ft_weights[:-11], ft_weights[-10:])
print('Reloading fine from', ft_weights_fine)
model_fine.set_weights(np.load(ft_weights_fine, allow_pickle=True))
return render_kwargs_train, render_kwargs_test, start, grad_vars, models
def config_parser():
import configargparse
parser = configargparse.ArgumentParser()
parser.add_argument('--config', is_config_file=True,
help='config file path')
parser.add_argument("--expname", type=str, help='experiment name')
parser.add_argument("--basedir", type=str, default='./logs/',
help='where to store ckpts and logs')
parser.add_argument("--datadir", type=str,
default='./data/llff/fern', help='input data directory')
# training options
parser.add_argument("--netdepth", type=int, default=8,
help='layers in network')
parser.add_argument("--netwidth", type=int, default=256,
help='channels per layer')
parser.add_argument("--netdepth_fine", type=int,
default=8, help='layers in fine network')
parser.add_argument("--netwidth_fine", type=int, default=256,
help='channels per layer in fine network')
parser.add_argument("--N_rand", type=int, default=32*32*4,
help='batch size (number of random rays per gradient step)')
parser.add_argument("--lrate", type=float,
default=5e-4, help='learning rate')
parser.add_argument("--lrate_decay", type=int, default=250,
help='exponential learning rate decay (in 1000s)')
parser.add_argument("--chunk", type=int, default=1024*32,
help='number of rays processed in parallel, decrease if running out of memory')
parser.add_argument("--netchunk", type=int, default=1024*64,
help='number of pts sent through network in parallel, decrease if running out of memory')
parser.add_argument("--no_batching", action='store_true',
help='only take random rays from 1 image at a time')
parser.add_argument("--no_reload", action='store_true',
help='do not reload weights from saved ckpt')
parser.add_argument("--ft_path", type=str, default=None,
help='specific weights npy file to reload for coarse network')
parser.add_argument("--random_seed", type=int, default=None,
help='fix random seed for repeatability')
# pre-crop options
parser.add_argument("--precrop_iters", type=int, default=0,
help='number of steps to train on central crops')
parser.add_argument("--precrop_frac", type=float,
default=.5, help='fraction of img taken for central crops')
# rendering options
parser.add_argument("--N_samples", type=int, default=64,
help='number of coarse samples per ray')
parser.add_argument("--N_importance", type=int, default=0,
help='number of additional fine samples per ray')
parser.add_argument("--perturb", type=float, default=1.,
help='set to 0. for no jitter, 1. for jitter')
parser.add_argument("--use_viewdirs", action='store_true',
help='use full 5D input instead of 3D')
parser.add_argument("--i_embed", type=int, default=0,
help='set 0 for default positional encoding, -1 for none')
parser.add_argument("--multires", type=int, default=10,
help='log2 of max freq for positional encoding (3D location)')
parser.add_argument("--multires_views", type=int, default=4,
help='log2 of max freq for positional encoding (2D direction)')
parser.add_argument("--raw_noise_std", type=float, default=0.,
help='std dev of noise added to regularize sigma_a output, 1e0 recommended')
parser.add_argument("--render_only", action='store_true',
help='do not optimize, reload weights and render out render_poses path')
parser.add_argument("--render_test", action='store_true',
help='render the test set instead of render_poses path')
parser.add_argument("--render_factor", type=int, default=0,
help='downsampling factor to speed up rendering, set 4 or 8 for fast preview')
# dataset options
parser.add_argument("--dataset_type", type=str, default='llff',
help='options: llff / blender / deepvoxels')
parser.add_argument("--testskip", type=int, default=8,
help='will load 1/N images from test/val sets, useful for large datasets like deepvoxels')
# deepvoxels flags
parser.add_argument("--shape", type=str, default='greek',
help='options : armchair / cube / greek / vase')
# blender flags
parser.add_argument("--white_bkgd", action='store_true',
help='set to render synthetic data on a white bkgd (always use for dvoxels)')
parser.add_argument("--half_res", action='store_true',
help='load blender synthetic data at 400x400 instead of 800x800')
# llff flags
parser.add_argument("--factor", type=int, default=8,
help='downsample factor for LLFF images')
parser.add_argument("--no_ndc", action='store_true',
help='do not use normalized device coordinates (set for non-forward facing scenes)')
parser.add_argument("--lindisp", action='store_true',
help='sampling linearly in disparity rather than depth')
parser.add_argument("--spherify", action='store_true',
help='set for spherical 360 scenes')
parser.add_argument("--llffhold", type=int, default=8,
help='will take every 1/N images as LLFF test set, paper uses 8')
# logging/saving options
parser.add_argument("--i_print", type=int, default=100,
help='frequency of console printout and metric loggin')
parser.add_argument("--i_img", type=int, default=500,
help='frequency of tensorboard image logging')
parser.add_argument("--i_weights", type=int, default=10000,
help='frequency of weight ckpt saving')
parser.add_argument("--i_testset", type=int, default=50000,
help='frequency of testset saving')
parser.add_argument("--i_video", type=int, default=50000,
help='frequency of render_poses video saving')
return parser
def train():
parser = config_parser()
args = parser.parse_args()
if args.random_seed is not None:
print('Fixing random seed', args.random_seed)
np.random.seed(args.random_seed)
tf.compat.v1.set_random_seed(args.random_seed)
# Load data
if args.dataset_type == 'llff':
images, poses, bds, render_poses, i_test = load_llff_data(args.datadir, args.factor,
recenter=True, bd_factor=.75,
spherify=args.spherify)
hwf = poses[0, :3, -1]
poses = poses[:, :3, :4]
print('Loaded llff', images.shape,
render_poses.shape, hwf, args.datadir)
if not isinstance(i_test, list):
i_test = [i_test]
if args.llffhold > 0:
print('Auto LLFF holdout,', args.llffhold)
i_test = np.arange(images.shape[0])[::args.llffhold]
i_val = i_test
i_train = np.array([i for i in np.arange(int(images.shape[0])) if
(i not in i_test and i not in i_val)])
print('DEFINING BOUNDS')
if args.no_ndc:
near = tf.reduce_min(bds) * .9
far = tf.reduce_max(bds) * 1.
else:
near = 0.
far = 1.
print('NEAR FAR', near, far)
elif args.dataset_type == 'blender':
images, poses, render_poses, hwf, i_split = load_blender_data(
args.datadir, args.half_res, args.testskip)
print('Loaded blender', images.shape,
render_poses.shape, hwf, args.datadir)
i_train, i_val, i_test = i_split
near = 2.
far = 6.
if args.white_bkgd:
images = images[..., :3]*images[..., -1:] + (1.-images[..., -1:])
else:
images = images[..., :3]
elif args.dataset_type == 'deepvoxels':
images, poses, render_poses, hwf, i_split = load_dv_data(scene=args.shape,
basedir=args.datadir,
testskip=args.testskip)
print('Loaded deepvoxels', images.shape,
render_poses.shape, hwf, args.datadir)
i_train, i_val, i_test = i_split
hemi_R = np.mean(np.linalg.norm(poses[:, :3, -1], axis=-1))
near = hemi_R-1.
far = hemi_R+1.
else:
print('Unknown dataset type', args.dataset_type, 'exiting')
return
# Cast intrinsics to right types
H, W, focal = hwf
H, W = int(H), int(W)
hwf = [H, W, focal]
if args.render_test:
render_poses = np.array(poses[i_test])
# Create log dir and copy the config file
basedir = args.basedir
expname = args.expname
os.makedirs(os.path.join(basedir, expname), exist_ok=True)
f = os.path.join(basedir, expname, 'args.txt')
with open(f, 'w') as file:
for arg in sorted(vars(args)):
attr = getattr(args, arg)
file.write('{} = {}\n'.format(arg, attr))
if args.config is not None:
f = os.path.join(basedir, expname, 'config.txt')
with open(f, 'w') as file:
file.write(open(args.config, 'r').read())
# Create nerf model
render_kwargs_train, render_kwargs_test, start, grad_vars, models = create_nerf(
args)
bds_dict = {
'near': tf.cast(near, tf.float32),
'far': tf.cast(far, tf.float32),
}
render_kwargs_train.update(bds_dict)
render_kwargs_test.update(bds_dict)
# Short circuit if only rendering out from trained model
if args.render_only:
print('RENDER ONLY')
if args.render_test:
# render_test switches to test poses
images = images[i_test]
else:
# Default is smoother render_poses path
images = None
testsavedir = os.path.join(basedir, expname, 'renderonly_{}_{:06d}'.format(
'test' if args.render_test else 'path', start))
os.makedirs(testsavedir, exist_ok=True)
print('test poses shape', render_poses.shape)
rgbs, _ = render_path(render_poses, hwf, args.chunk, render_kwargs_test,
gt_imgs=images, savedir=testsavedir, render_factor=args.render_factor)
print('Done rendering', testsavedir)
imageio.mimwrite(os.path.join(testsavedir, 'video.mp4'),
to8b(rgbs), fps=30, quality=8)
return
# Create optimizer
lrate = args.lrate
if args.lrate_decay > 0:
lrate = tf.keras.optimizers.schedules.ExponentialDecay(lrate,
decay_steps=args.lrate_decay * 1000, decay_rate=0.1)
optimizer = tf.keras.optimizers.Adam(lrate)
models['optimizer'] = optimizer
global_step = tf.compat.v1.train.get_or_create_global_step()
global_step.assign(start)
# Prepare raybatch tensor if batching random rays
N_rand = args.N_rand
use_batching = not args.no_batching
if use_batching:
# For random ray batching.
#
# Constructs an array 'rays_rgb' of shape [N*H*W, 3, 3] where axis=1 is
# interpreted as,
# axis=0: ray origin in world space
# axis=1: ray direction in world space
# axis=2: observed RGB color of pixel
print('get rays')
# get_rays_np() returns rays_origin=[H, W, 3], rays_direction=[H, W, 3]
# for each pixel in the image. This stack() adds a new dimension.
rays = [get_rays_np(H, W, focal, p) for p in poses[:, :3, :4]]
rays = np.stack(rays, axis=0) # [N, ro+rd, H, W, 3]
print('done, concats')
# [N, ro+rd+rgb, H, W, 3]
rays_rgb = np.concatenate([rays, images[:, None, ...]], 1)
# [N, H, W, ro+rd+rgb, 3]
rays_rgb = np.transpose(rays_rgb, [0, 2, 3, 1, 4])
rays_rgb = np.stack([rays_rgb[i]
for i in i_train], axis=0) # train images only
# [(N-1)*H*W, ro+rd+rgb, 3]
rays_rgb = np.reshape(rays_rgb, [-1, 3, 3])
rays_rgb = rays_rgb.astype(np.float32)
print('shuffle rays')
np.random.shuffle(rays_rgb)
print('done')
i_batch = 0
N_iters = 1000000
print('Begin')
print('TRAIN views are', i_train)
print('TEST views are', i_test)
print('VAL views are', i_val)
# Summary writers
writer = tf.contrib.summary.create_file_writer(
os.path.join(basedir, 'summaries', expname))
writer.set_as_default()
for i in range(start, N_iters):
time0 = time.time()
# Sample random ray batch
if use_batching:
# Random over all images
batch = rays_rgb[i_batch:i_batch+N_rand] # [B, 2+1, 3*?]
batch = tf.transpose(batch, [1, 0, 2])
# batch_rays[i, n, xyz] = ray origin or direction, example_id, 3D position
# target_s[n, rgb] = example_id, observed color.
batch_rays, target_s = batch[:2], batch[2]
i_batch += N_rand
if i_batch >= rays_rgb.shape[0]:
np.random.shuffle(rays_rgb)
i_batch = 0
else:
# Random from one image
img_i = np.random.choice(i_train)
target = images[img_i]
pose = poses[img_i, :3, :4]
if N_rand is not None:
rays_o, rays_d = get_rays(H, W, focal, pose)
if i < args.precrop_iters:
dH = int(H//2 * args.precrop_frac)
dW = int(W//2 * args.precrop_frac)
coords = tf.stack(tf.meshgrid(
tf.range(H//2 - dH, H//2 + dH),
tf.range(W//2 - dW, W//2 + dW),
indexing='ij'), -1)
if i < 10:
print('precrop', dH, dW, coords[0,0], coords[-1,-1])
else:
coords = tf.stack(tf.meshgrid(
tf.range(H), tf.range(W), indexing='ij'), -1)
coords = tf.reshape(coords, [-1, 2])
select_inds = np.random.choice(
coords.shape[0], size=[N_rand], replace=False)
select_inds = tf.gather_nd(coords, select_inds[:, tf.newaxis])
rays_o = tf.gather_nd(rays_o, select_inds)
rays_d = tf.gather_nd(rays_d, select_inds)
batch_rays = tf.stack([rays_o, rays_d], 0)
target_s = tf.gather_nd(target, select_inds)
##### Core optimization loop #####
with tf.GradientTape() as tape:
# Make predictions for color, disparity, accumulated opacity.
rgb, disp, acc, extras = render(
H, W, focal, chunk=args.chunk, rays=batch_rays,
verbose=i < 10, retraw=True, **render_kwargs_train)
# Compute MSE loss between predicted and true RGB.
img_loss = img2mse(rgb, target_s)
trans = extras['raw'][..., -1]
loss = img_loss
psnr = mse2psnr(img_loss)
# Add MSE loss for coarse-grained model
if 'rgb0' in extras:
img_loss0 = img2mse(extras['rgb0'], target_s)
loss += img_loss0
psnr0 = mse2psnr(img_loss0)
gradients = tape.gradient(loss, grad_vars)
optimizer.apply_gradients(zip(gradients, grad_vars))
dt = time.time()-time0
##### end #####
# Rest is logging
def save_weights(net, prefix, i):
path = os.path.join(
basedir, expname, '{}_{:06d}.npy'.format(prefix, i))
np.save(path, net.get_weights())
print('saved weights at', path)
if i % args.i_weights == 0:
for k in models:
save_weights(models[k], k, i)
if i % args.i_video == 0 and i > 0:
rgbs, disps = render_path(
render_poses, hwf, args.chunk, render_kwargs_test)
print('Done, saving', rgbs.shape, disps.shape)
moviebase = os.path.join(
basedir, expname, '{}_spiral_{:06d}_'.format(expname, i))
imageio.mimwrite(moviebase + 'rgb.mp4',
to8b(rgbs), fps=30, quality=8)
imageio.mimwrite(moviebase + 'disp.mp4',
to8b(disps / np.max(disps)), fps=30, quality=8)
if args.use_viewdirs:
render_kwargs_test['c2w_staticcam'] = render_poses[0][:3, :4]
rgbs_still, _ = render_path(
render_poses, hwf, args.chunk, render_kwargs_test)
render_kwargs_test['c2w_staticcam'] = None
imageio.mimwrite(moviebase + 'rgb_still.mp4',
to8b(rgbs_still), fps=30, quality=8)
if i % args.i_testset == 0 and i > 0:
testsavedir = os.path.join(
basedir, expname, 'testset_{:06d}'.format(i))
os.makedirs(testsavedir, exist_ok=True)
print('test poses shape', poses[i_test].shape)
render_path(poses[i_test], hwf, args.chunk, render_kwargs_test,
gt_imgs=images[i_test], savedir=testsavedir)
print('Saved test set')
if i % args.i_print == 0 or i < 10:
print(expname, i, psnr.numpy(), loss.numpy(), global_step.numpy())
print('iter time {:.05f}'.format(dt))
with tf.contrib.summary.record_summaries_every_n_global_steps(args.i_print):
tf.contrib.summary.scalar('loss', loss)
tf.contrib.summary.scalar('psnr', psnr)
tf.contrib.summary.histogram('tran', trans)
if args.N_importance > 0:
tf.contrib.summary.scalar('psnr0', psnr0)
if i % args.i_img == 0:
# Log a rendered validation view to Tensorboard
img_i = np.random.choice(i_val)
target = images[img_i]
pose = poses[img_i, :3, :4]
rgb, disp, acc, extras = render(H, W, focal, chunk=args.chunk, c2w=pose,
**render_kwargs_test)
psnr = mse2psnr(img2mse(rgb, target))
# Save out the validation image for Tensorboard-free monitoring
testimgdir = os.path.join(basedir, expname, 'tboard_val_imgs')
if i==0:
os.makedirs(testimgdir, exist_ok=True)
imageio.imwrite(os.path.join(testimgdir, '{:06d}.png'.format(i)), to8b(rgb))
with tf.contrib.summary.record_summaries_every_n_global_steps(args.i_img):
tf.contrib.summary.image('rgb', to8b(rgb)[tf.newaxis])
tf.contrib.summary.image(
'disp', disp[tf.newaxis, ..., tf.newaxis])
tf.contrib.summary.image(
'acc', acc[tf.newaxis, ..., tf.newaxis])
tf.contrib.summary.scalar('psnr_holdout', psnr)
tf.contrib.summary.image('rgb_holdout', target[tf.newaxis])
if args.N_importance > 0:
with tf.contrib.summary.record_summaries_every_n_global_steps(args.i_img):
tf.contrib.summary.image(
'rgb0', to8b(extras['rgb0'])[tf.newaxis])
tf.contrib.summary.image(
'disp0', extras['disp0'][tf.newaxis, ..., tf.newaxis])
tf.contrib.summary.image(
'z_std', extras['z_std'][tf.newaxis, ..., tf.newaxis])
global_step.assign_add(1)
if __name__ == '__main__':
train()