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cameras.py
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cameras.py
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"""
@file cameras.py
@author Jianfei Guo, Shanghai AI Lab
@brief Special kinds of SceneNode: camera observers.
Support 3 kinds of usage:
- single camera `Camera` slice_at single frame
- single camera `Camera` slice_at batched multi frames
- bundled multiple camera `MultiCamBundle` slice_at single frame
"""
__all__ = [
"namedtuple_mask_nuvd",
"namedtuple_mask_niuvd",
"Camera",
"MultiCamBundle",
"CAMERA_CLASS_NAMES"
]
import numpy as np
from typing import NamedTuple, List, Tuple, Any
import torch
import torch.nn.functional as F
from nr3d_lib.utils import is_scalar
from nr3d_lib.models.attributes import *
from nr3d_lib.graphics.cameras import pinhole_lift, sphere_inside_frustum
from app.resources.nodes import SceneNode
CAMERA_CLASS_NAMES = ['Camera']
class namedtuple_mask_nuvd(NamedTuple):
mask: torch.Tensor
n: int
u: torch.Tensor
v: torch.Tensor
d: torch.Tensor
class namedtuple_mask_niuvd(NamedTuple):
mask: torch.Tensor
n: int
i: torch.Tensor
u: torch.Tensor
v: torch.Tensor
d: torch.Tensor
class Camera(SceneNode):
def __init__(self, unique_id: str, scene=..., device=None, dtype=torch.float):
super().__init__(unique_id=unique_id, class_name='Camera', scene=scene, device=device, dtype=dtype)
# Additional attributes
self.intr = CameraBase(device=device)
self.exposure = Scalar(device=device)
self.near = None
self.far = None
self.frustum = None # [..., num_frustum_planes, 4(n3+d1)]
# self.min_radial_dist = None
# self.max_radial_dist = None
self.rolling_shutter_effect = False
# @profile
def update(self):
SceneNode.update(self)
# Update view frustum
with torch.no_grad():
self.build_view_frustum()
def _parse_attr_data(self, odict: dict, data: dict, device=None) -> dict:
"""
Parses custom camera node data from `scenario.pt`, in addition to the common nodes' `transform` and `scale`.
"""
#---- Parse basic transform, scale data.
parsed_attr_data = super()._parse_attr_data(odict, data, device=device)
#---- Parse camera intrinsics
if 'intr' in data:
#---- Get camera_model from odict
camera_model: str = odict.get('camera_model', 'pinhole').lower()
hw = data['hw'].astype(np.float32)
intr_dict = dict(H=hw[:,0], W=hw[:,1], device=device)
if camera_model == 'pinhole':
intr_dict['mat'] = CameraMatrix3x3(data['intr'][..., :3, :3], dtype=torch.float, device=device)
intr = PinholeCameraMatHW(**intr_dict)
elif camera_model == 'opencv':
distortion = data['distortion']
intr_dict['mat'] = CameraMatrix3x3(data['intr'][..., :3, :3], dtype=torch.float, device=device)
intr_dict['distortion'] = make_vector(distortion.shape[-1])(distortion, dtype=torch.float, device=device)
intr = OpenCVCameraMatHW(**intr_dict)
elif camera_model == 'fisheye':
distortion = data['distortion']
intr_dict['mat'] = CameraMatrix3x3(data['intr'][..., :3, :3], dtype=torch.float, device=device)
intr_dict['distortion'] = make_vector(distortion.shape[-1])(distortion, dtype=torch.float, device=device)
intr = FisheyeCameraMatHW(**intr_dict)
else:
raise RuntimeError(f"Invalid camera_model={camera_model}")
parsed_attr_data.update(intr=intr)
#---- Parse exposure information
if 'exposure' in data:
# TODO: Might get exposure type from odict (if there are any other types other than scalars)
parsed_attr_data.update(exposure=Scalar(data['exposure'], device=device))
#---- Parse rolling shutter effect information
self.rolling_shutter_effect = odict.get('rolling_shutter_effect', False)
return parsed_attr_data
@torch.no_grad()
# @profile
def get_view_frustum(self, near: float=None, far: float=None) -> torch.Tensor:
""" Calculate view frustum boundary planes with given near, far clip
- support single frame: ✓
- support batched frames: ✓ `...` means arbitary prefix-dims (i.e. `self.i_prefix`)
Args:
near (float, optional): The given near clip value. Defaults to None.
far (float, optional): The given far clip value. Defaults to None.
Returns:
torch.Tensor: [..., num_frustum_planes, 4] The calculated frustum border planes representation.
The last dim 4 = 3 (normals) + 1 (distances)
"""
c2w = self.world_transform.mat_4x4()
planes = self.intr.get_view_frustum(
c2w, near=self.near if near is None else near, far=self.far if far is None else far)
return planes
# @profile
def build_view_frustum(self):
""" Build view frustum by calculating frustum planes repr
- support single frame: ✓
- support batched frames: ✓ `...` means arbitary prefix-dims (i.e. `self.i_prefix`)
"""
self.frustum = self.get_view_frustum() # [..., num_frustum_planes, 4(n3+d1)]
@torch.no_grad()
def get_view_frustum_pts(self, near: float=None, far: float=None)-> torch.Tensor:
""" Get view frustum vertices with given near, far clip
- support single frame: ✓
- support batched frames: ✓ `...` means arbitary prefix-dims (i.e. `self.i_prefix`)
Args:
near (float, optional): The given near clip value. Defaults to None.
far (float, optional): The given far clip value. Defaults to None.
Returns:
torch.Tensor: [..., 8, 3] The vertices of the view frustum(s)
"""
near_clip = (0. if self.near is None else self.near) if near is None else near
far_clip = (100.0 if self.far is None else self.far) if far is None else far
_W, _H = self.intr.wh().movedim(-1,0)
_0, _near, _far = _W.new_zeros(_W.shape), _W.new_full(_W.shape, near_clip), _W.new_full(_W.shape, far_clip)
# [..., 8]
u, v, d = torch.stack(
[
torch.stack([_0, _0, _near], 0),
torch.stack([_W, _0, _near], 0),
torch.stack([_W, _H, _near], 0),
torch.stack([_0, _H, _near], 0),
torch.stack([_0, _0, _far], 0),
torch.stack([_W, _0, _far], 0),
torch.stack([_W, _H, _far], 0),
torch.stack([_0, _H, _far], 0),
], dim=-1
)
# [..., 8, 3]
# pts = self.intr.lift(u, v, d)[...,:3]
# pts = self.world_transform(pts)
mat = self.intr.mat_3x3()
if len(mat_prefix:=mat.shape[:-2]) > 0:
mat = mat.view(*mat_prefix, *[1]*(u.dim()-len(mat_prefix)), 3, 3)
# [..., 8, 3]
# NOTE: Force to use pinhole lift instead.
pts = pinhole_lift(u, v, d, mat)[..., :3]
pts = self.world_transform(pts)
return pts
def check_spheres_inside_frustum(self, sphere_center_radius: torch.Tensor, holistic_body=False) -> torch.BoolTensor:
""" Check spheres inside camera frustum
- support single frame: ✓
- support batched frames: ✓ `...` means arbitary prefix-dims (i.e. `self.i_prefix`)
Args:
sphere_center_radius (torch.Tensor): [..., num_spheres, 4], The given spheres repr, last dim = center (3) + radius (1)
holistic_body (bool, optional): Whether the holistic sphere body must be in the planes (T), or any part counts (F). Defaults to False.
Returns:
torch.BoolTensor: [..., num_spheres] Inside checks of the given spheres
"""
inside = sphere_inside_frustum(sphere_center_radius, self.frustum, holistic=holistic_body)
return inside
# @profile
def filter_drawable_groups(self, drawables: List[SceneNode], draw_self=False) -> List[SceneNode]:
""" Frustum culling to filter drawables by checking whether drawables' bounding spheres has intersection with view frustums.
- support single frame: ✓
- support batched frames: ✓ `...` means arbitary prefix-dims (i.e. `self.i_prefix`)
Args:
drawables (List[SceneNode]): List of drawables
draw_self (bool, optional): Whether draw self node. Defaults to False.
Returns:
List[SceneNode]: The filtered list of drawables
"""
# For now, we don't consider observer's self shading
if self.model is not None and not draw_self:
drawables = list(filter(lambda obj: obj.id!=self.id, drawables))
if len(collected:=[[obj, obj.model_bounding_sphere, obj.i_valid_flags] for obj in drawables if obj.model_bounding_sphere is not None]) > 0:
drawables_with_bound, model_bounding_spheres, obj_valids = zip(*collected)
else:
drawables_with_bound = []
drawables_no_bound = [obj for obj in drawables if obj.model_bounding_sphere is None]
# Frustum Culling
if len(drawables_with_bound) > 0:
# Only on nodes that has Bounding
model_bounding_spheres, obj_valids = torch.stack(model_bounding_spheres, -2), torch.stack(obj_valids, -1)
# NOTE: `...` means arbitary prefix-dims (i.e. `self.i_prefix`)
# model_bounding_spheres: [..., num_drawables, 4]
# obj_valids: [..., num_drawables]
# self.frustum: [..., num_planes, 4]
# inside: [..., num_drawables]
inside = self.check_spheres_inside_frustum(model_bounding_spheres) & obj_valids
if (dims:=inside.dim()) > 1:
# NOTE: Dealing with multiple cameras or batched frames: \
# if any camera / frame suffices, then this drawable node suffices.
inside = inside.any(dim=0) if dims == 2 else (inside.sum(dim=list(range(0,dims-1))) > 0)
# List [num_drawables]
inside = inside.data.nonzero(as_tuple=True)[0].tolist()
drawables_with_bound = [drawables_with_bound[i] for i in inside]
return drawables_with_bound + drawables_no_bound
def sample_pixel(self, num_samples: int) -> torch.Tensor:
""" Uniformly sample some pixels xy locations.
- support single frame: ✓
- support batched frames: ✓ `...` means arbitary prefix-dims (i.e. `self.i_prefix`)
Args:
num_samples (int): The given number of samples
Returns:
torch.Tensor: [..., num_samples, 2] The sampled xy locations, within range [0,1]
"""
xy = torch.rand([*self.i_prefix, num_samples, 2], dtype=self.dtype, device=self.device).clamp_(1e-6, 1-1e-6)
return xy
def _get_selected_rays_from_xy(self, xy: torch.Tensor, *, snap_to_pixel_centers=True) -> Tuple[torch.Tensor, torch.Tensor]:
""" Lift [0,1] xy pixel locations to 3D rays origins and direction vectors.
- support single frame: ✓
- support batched frames: ✓ `...` means arbitary prefix-dims (i.e. `self.i_prefix`)
NOTE: Support different camera H,W in different batch
Args:
xy (torch.Tensor): [..., 2] The given xy locations within range [0,1]
snap_to_pixel_centers (bool, optional): Whether to snap pixel locations onto pixel borders. Defaults to True.
Returns:
Tuple[torch.Tensor, torch.Tensor]: [..., 3], [..., 3] The lifted rays_o and rays_d vectors
"""
intrs, c2ws, prefix = self.intr, self.world_transform, list(self.i_prefix)
# If batched: Assume `xy` has the same prefix dims as self.i_prefix;
assert list(xy.shape[:len(prefix)]) == prefix, f"Expects xy to have shape of {prefix + [Ellipsis]}, but currently xy.shape={xy.shape}"
WH = intrs.wh().long()
WH = WH.view(*WH.shape[:-1], *[1]*(xy.dim()-WH.dim()), 2)
if snap_to_pixel_centers:
wh = (xy*WH).long().clamp_(WH.new_zeros([]), WH-1)+0.5
else:
wh = xy*WH
lifted_directions = intrs.lift(wh[..., 0], wh[..., 1], wh.new_ones(wh.shape[:-1]))
rays_d = F.normalize(c2ws.rotate(lifted_directions[..., :3]), dim=-1)
trans = c2ws.translation()
rays_o = trans.view(*trans.shape[:-1], *[1]*(xy.dim()-trans.dim()), 3).expand_as(rays_d)
return rays_o, rays_d
def _get_selected_rays_from_ixy(self, i: torch.Tensor, xy: torch.Tensor, *, snap_to_pixel_centers=True) -> Tuple[torch.Tensor, torch.Tensor]:
""" Lift [0,1] xy pixel locations at given indices to rays origins and direction vectors.
The meaning of `i` varies differently in different use cases.
There are two possible use cases:
- Camera @ batched frames; where `i` indicates the indices of multiple frames.
- MultiCamBundle @ single frame; where `i` indicates the indices of multiple cameras.
Args:
i (torch.Tensor): [..., ] The given selector indices to slice the attr's prefix-dim
xy (torch.Tensor): [..., 2] The given xy locations within range [0,1]
snap_to_pixel_centers (bool, optional): Whether to snap pixel locations onto pixel borders. Defaults to True.
Returns:
Tuple[torch.Tensor, torch.Tensor]: [..., 3], [..., 3] The lifted rays_o and rays_d vectors
"""
prefix = tuple(i.shape)
assert list(xy.shape[:len(prefix)]) == list(prefix), f"Expects xy to have shape of {prefix + [Ellipsis]}, but currently xy.shape={xy.shape}"
intrs, c2ws = self.intr[i], self.world_transform[i]
WH = intrs.wh().long()
if snap_to_pixel_centers:
wh = (xy*WH).long().clamp_(WH.new_zeros([]), WH-1)+0.5
else:
wh = xy*WH
lifted_directions = intrs.lift(wh[..., 0], wh[..., 1], wh.new_ones(wh.shape[:-1]))
rays_d = F.normalize(c2ws.rotate(lifted_directions[..., :3]), dim=-1)
rays_o = c2ws.translation()
return rays_o, rays_d
def get_selected_rays(self, *, sel: torch.Tensor = None, xy: torch.Tensor = ..., snap_to_pixel_centers=True) -> Tuple[torch.Tensor, torch.Tensor]:
""" Lift pixel locations to rays_o and rays_d vectors
- support single frame: x NOTE: This function should only be called when in batched.
- support batched frames: ✓
NOTE: Support different camera H,W in different batch
Args:
sel (torch.Tensor, optional): [..., ] The given selector indices to slice the attr's prefix-dim. \
Defaults to None.
xy (torch.Tensor): [..., 2] The given xy locations within range [0,1]
snap_to_pixel_centers (bool, optional): Whether to snap pixel locations onto pixel borders. Defaults to True.
Returns:
Tuple[torch.Tensor, torch.Tensor]: [..., 3], [..., 3] The lifted rays_o and rays_d vectors
"""
if sel is not None:
return self._get_selected_rays_from_ixy(sel, xy, snap_to_pixel_centers=snap_to_pixel_centers)
else:
return self._get_selected_rays_from_xy(xy, snap_to_pixel_centers=snap_to_pixel_centers)
def get_all_rays(self, return_rays=True, return_ts=False, return_ij=False, return_xy=False) -> List[torch.Tensor]:
""" Get all camera rays of full image(s)
- support single frame: ✓
- support batched frames: o should only be used when H or W is the same across differerent batches.
Args:
return_rays (bool, optional): Whether return lifted rays_o and rays_d vectors. Defaults to True.
return_ij (bool, optional): Whether return ij pixel locations (i \in [0,W], j \in [0,H]). Defaults to False.
return_xy (bool, optional): Whether return xy pixel locations (xy \in [0,1]). Defaults to False.
Returns:
List[torch.Tensor]: Only rays_o, rays_d, or also appends ij or xy.
"""
H, W, device = self.intr.H, self.intr.W, self.device
i, j = torch.meshgrid(torch.linspace(0, W-1, W, device=device), torch.linspace(0, H-1, H, device=device), indexing='xy')
i, j = i.reshape(H*W), j.reshape(H*W)
w, h = i+0.5, j+0.5 # Pixel centers
rays_xy = torch.stack([w / W, h / H], dim=-1)
ret = []
if return_rays:
lifted_directions = self.intr.lift(w, h, torch.ones_like(w, device=device))
# NOTE: !!! bmm/mm would introduce errors of 4e-3 magnitude to rays_d,
# which would be broadcasted to coordinate x and enlarged to an error of ~0.1 @(depth=10) and ~1.0 @(depth=100)
# DO NOT USE bmm/mm !!! (also, einsum falls back to bmm/mm)
# rays_d = torch.mm(self.c2w.rotation(), lifted_directions[...,:3].transpose(-1,-2)).transpose(-1, -2)[..., :3]
# rays_d = torch.einsum('ij,...j->...i', self.c2w.rotation(), lifted_directions[..., :3])
rays_d = F.normalize(self.world_transform.rotate(lifted_directions[..., :3]), dim=-1)
rays_o = self.world_transform.translation()[..., None, :].expand_as(rays_d)
ret = [rays_o, rays_d]
if return_ts:
if [*self.i_prefix] == list(rays_o.shape[:-1]):
rays_i = self.i
else:
cam_i = self.i.item() if isinstance(self.i, (torch.Tensor, np.ndarray)) else self.i
rays_i = torch.full(rays_o.shape[:-1], cam_i, dtype=torch.long, device=rays_o.device)
if self.i_is_timestamp: # `self.i` represents timestamps
rays_ts = self.get_timestamps(ts_base=rays_i, pix=rays_xy)
else: # `self.i` represents frame indices
rays_ts = self.get_timestamps(fi=rays_i, pix=rays_xy)
ret.append(rays_ts)
if return_ij:
rays_ij = torch.stack([i, j], dim=-1)
ret.append(rays_ij)
if return_xy:
ret.append(rays_xy)
return ret
def get_timestamps(self, *, fi: torch.Tensor = None, ts_base: torch.Tensor = None, pix: torch.Tensor = None):
assert bool(ts_base is not None) != bool(fi is not None), f"You should specify one of [fi, ts_base]"
if ts_base is None:
ts_base = self.frame_global_ts[fi]
if not self.rolling_shutter_effect:
return ts_base
raise NotImplementedError
assert pix is not None, \
f"Requires pixel location in [0,1] `pix` to calculate timestamp for each ray to account for rolling shutter effect."
ts_base = check_to_torch(ts_base, device=pix.device, dtype=self.frame_global_ts.dtype)
ts_base = ts_base.expand([*pix.shape[:-1]])
# TODO: Add timestamp offset to each ray here
def project_pts_in_image(self, pts: torch.Tensor, *, ignore_mask: torch.Tensor = None, near_clip: float=1e-4):
""" Project 3D points into image(s)
- support single frame: ✓
- support batched frames: ✓
Args:
pts (torch.Tensor): [..., num_points, 3] The given 3D points, `...` has the same prefix dims as self.i_prefix;
ignore_mask (torch.Tensor, optional): Optionally ignores projected pts that falls inside this mask. Defaults to None.
near_clip (float, optional): Clip away too close points as their u,v is usally in-correct. Defaults to 1e-4.
Returns:
Union[namedtuple_mask_nuvd, namedtuple_mask_niuvd]: The projection results
"""
intrs, c2ws, prefix = self.intr, self.world_transform, self.i_prefix
# If batched: Assume `pts` has the same prefix dims as self.i_prefix;
# pts.shape == [*prefix, num_points, 3] or [*[1]*len(prefix), num_points, 3]
assert pts.dim() == (len(prefix) + 2), f"Expect pts to be of shape {[*prefix, 'N', 3]} or {[*[1]*len(prefix), 'N', 3]}"
W, H = intrs.wh().long().movedim(-1,0).view(2, *prefix, *[1]*(pts.dim()-len(prefix)-1))
u, v, d = self.intr.proj(c2ws(pts, inv=True))
mask = (d > near_clip) & (u < W) & (u >= 0) & (v < H) & (v >= 0)
inds = mask.nonzero(as_tuple=True)
n, u, v, d = inds[0].numel(), u[inds].long(), v[inds].long(), d[inds]
if len(prefix) == 0:
if ignore_mask is not None:
suffice = (~ignore_mask[v.long(),u.long()])
suffice_pi = suffice.nonzero().long()[..., 0] # Pixel indices that will not be ignored by `ignore_mask`
mask[inds] = suffice
n, u, v, d = suffice_pi.numel(), u[suffice_pi], v[suffice_pi], d[suffice_pi]
return namedtuple_mask_nuvd(mask, n, u, v, d)
elif len(prefix) == 1:
# NOTE: Index of the prefix-dim.
# For Camera + batched frames, these are the indices of multiple frames
# For MultiCamBundle + single frame, these are the indices of multiple cameras
i = inds[0]
if ignore_mask is not None:
suffice = ~ignore_mask[i,v.long(),u.long()]
suffice_pi = suffice.nonzero().long()[..., 0] # Pixel indices that will not be ignored by `ignore_mask`
mask[inds] = suffice
n, i, u, v, d = suffice_pi.numel(), i[suffice_pi], u[suffice_pi], v[suffice_pi], d[suffice_pi]
return namedtuple_mask_niuvd(mask, n, i, u, v, d)
else:
raise RuntimeError(f"`project_pts_in_image` does not support current i_prefix={self.i_prefix}")
@staticmethod
def make_bundle(l: List['Camera']):
return MultiCamBundle(l)
class MultiCamBundle(object):
def __init__(self, cams: List[Camera], ci: torch.LongTensor = None):
self.class_name = 'Camera' # TODO
for cam in cams:
if not cam.i_is_single:
assert ci is not None, \
f"Requires `ci` to gather multiple cameras when frozen at multiple frames."
assert [*ci.shape] == list(cam.i_prefix), \
f"`ci` (shape={[*ci.shape]}) should have the same shape with "\
f"the current frozen prefix `cam.i_prefix`={list(cam.i_prefix)}"
# assert is_scalar(cam.i), "Only support bundling cameras that are frozen at a single time."
self.dtype = cam.dtype
self.device = cam.device
self.scene = cam.scene
self.cams = cams
self.id = [cam.id for cam in cams]
nears = [cam.near for cam in cams if cam.near is not None]
fars = [cam.far for cam in cams if cam.far is not None]
self.near = None if len(nears) == 0 else min(nears)
self.far = None if len(fars) == 0 else max(fars)
intrs = [cam.intr for cam in cams]
lst_world_transform = [cam.world_transform for cam in cams]
self.i_prefix = (len(cams),*cam.i_prefix)
self.intr = type(cams[0].intr).stack(intrs)
self.world_transform = type(cams[0].world_transform).stack(lst_world_transform)
self.frustum = torch.stack([cam.frustum for cam in cams], 0)
global_ts = [cam.frame_global_ts for cam in cams if cam.frame_global_ts is not None]
self.frame_global_ts = torch.stack(global_ts, 0) if (len(global_ts) == len(cams)) else None
global_fi = [cam.frame_global_fi for cam in cams if cam.frame_global_fi is not None]
self.frame_global_fi = torch.stack(global_fi, 0) if (len(global_fi) == len(cams)) else None
# Whether the camera id selection is already done when grouping multiple cameras.
self.already_selected = False
if ci is not None:
# Use `ci` to select the cameras, keeping other dimensions untouched (gather)
self.already_selected = True
self.i_prefix = (*cam.i_prefix, )
self.world_transform = self.world_transform.take_along_dim(ci.unsqueeze(0), dim=0)[0]
self.intr = self.intr.take_along_dim(ci.unsqueeze(0), dim=0)[0]
self.frustum = torch.take_along_dim(self.frustum, ci[None,...,None,None], dim=0)[0]
self.frame_global_ts = torch.take_along_dim(self.frame_global_ts, ci.unsqueeze(0))[0]
self.frame_global_fi = torch.take_along_dim(self.frame_global_fi, ci.unsqueeze(0))[0]
def check_spheres_inside_frustum(self, sphere_center_radius: torch.Tensor, holistic_body=False):
return Camera.check_spheres_inside_frustum(self, sphere_center_radius, holistic_body=holistic_body)
def filter_drawable_groups(self, drawables: List[SceneNode], draw_self=False) -> List[SceneNode]:
if len(collected:=[[obj, obj.model_bounding_sphere, obj.i_valid_flags] for obj in drawables if obj.model_bounding_sphere is not None]) > 0:
drawables_with_bound, model_bounding_spheres, obj_valids = zip(*collected)
else:
drawables_with_bound = []
drawables_no_bound = [obj for obj in drawables if obj.model_bounding_sphere is None]
# Frustum Culling
if len(drawables_with_bound) > 0:
# Only on nodes that has Bounding
model_bounding_spheres, obj_valids = torch.stack(model_bounding_spheres, -2).unsqueeze(0), torch.stack(obj_valids, -1).unsqueeze(0)
# NOTE: model_bounding_spheres: [1, num_drawables, 4]
# obj_valids: [1, num_drawables, ]
# self.frustum: [num_cameras, num_planes, 4]
# inside: [num_cameras, num_drawables]
inside = self.check_spheres_inside_frustum(model_bounding_spheres) & obj_valids
if (dims:=inside.dim()) > 1:
# Dealing with multiple cameras or batched frames: if any camera suffices, then this drawable node suffices.
inside = inside.any(dim=0) if dims == 2 else (inside.sum(dim=list(range(0,dims-1))) > 0)
# List [num_drawables]
inside = inside.data.nonzero(as_tuple=True)[0].tolist()
drawables_with_bound = [drawables_with_bound[i] for i in inside]
return drawables_with_bound + drawables_no_bound
def sample_pixel(self, num_samples: int):
return Camera.sample_pixel(self, num_samples)
def get_selected_rays(self, *, sel: torch.Tensor = None, xy: torch.Tensor = None, snap_to_pixel_centers=True):
return Camera.get_selected_rays(self, sel=sel, xy=xy, snap_to_pixel_centers=snap_to_pixel_centers)
def get_all_rays(self):
raise RuntimeError(f"You should not use `get_all_rays` on {self.__class__.__name__}. Please use {Camera.__name__} instead.")
def project_pts_in_image(self, pts: torch.Tensor, *, ignore_mask: torch.Tensor = None, near_clip: float=1e-4):
return Camera.project_pts_in_image(self, pts, ignore_mask=ignore_mask, near_clip=near_clip)
if __name__ == "__main__":
def unit_test(
device=torch.device('cuda'),
# device=torch.device('cpu'),
):
from icecream import ic
from nr3d_lib.utils import import_str
from nr3d_lib.config import ConfigDict
from nr3d_lib.models.spatial import AABBSpace
from app.resources import create_scene_bank
from dataio.scene_dataset import SceneDataset
dataset_cfg = ConfigDict(
target="dataio.autonomous_driving.WaymoDataset",
param=ConfigDict(
root="/data1/waymo/processed/",
rgb_dirname="images",
lidar_dirname="lidars",
mask_dirname="masks"
)
)
scenebank_cfg = ConfigDict(
scenarios=['segment-6207195415812436731_805_000_825_000_with_camera_labels, 0, 150'],
observer_cfgs=ConfigDict(
Camera=ConfigDict(
list=['camera_FRONT', 'camera_FRONT_LEFT', 'camera_FRONT_RIGHT', 'camera_SIDE_LEFT', 'camera_SIDE_RIGHT']
)
),
object_cfgs=ConfigDict(
Vehicle=ConfigDict(dynamic_only=False)
),
on_load=ConfigDict(
consider_distortion=False,
no_objects=False, scene_graph_has_ego_car=True, correct_extr_for_timestamp_difference=True
)
)
dataset_impl: SceneDataset = import_str(dataset_cfg.target)(dataset_cfg.param)
scene_bank, scenebank_meta = create_scene_bank(
dataset=dataset_impl, device=device,
scenebank_cfg=scenebank_cfg,
drawable_class_names=['Sky', 'Street', 'Vehicle'],
misc_node_class_names=['node', 'Ego', 'EgoVehicle', 'EgoDrone'],
)
scene = scene_bank[0]
# Add some dummy object with model and bound
class Dummy(object):
id: str
space: Any
dummy_model = Dummy()
dummy_model.id = 'dummy'
dummy_model.space = AABBSpace(bounding_size=2.0, device=device)
for o in scene.all_nodes_by_class_name['Vehicle']:
o.model = dummy_model
scene.add_node_to_drawable(o)
#--------------------- Slice with batched frame inds
scene.slice_at([20,21,22,23,24])
# Single camera (but support batched frame inds)
cam: Camera = scene.get_observer_groups_by_class_name('Camera', True)[0]
cam.filter_drawable_groups(scene.get_drawables(True))
xy = cam.sample_pixel(4096)
rays_o, rays_d = cam.get_selected_rays(xy=xy)
fi = torch.randint(5, (4096,), dtype=torch.long, device=device)
xy = torch.rand([4096, 2], dtype=torch.float, device=device)
rays_o, rays_d = cam.get_selected_rays(sel=fi, xy=xy)
pts = torch.randn([5, 800, 3], dtype=torch.float, device=device) + cam.world_transform.translation()[:,None,:]
ret = cam.project_pts_in_image(pts)
pts = cam.get_view_frustum_pts()
#--------------------- Slice with single frame ind
scene.slice_at(20)
cam: Camera = scene.get_observer_groups_by_class_name('Camera', True)[0]
cam.filter_drawable_groups(scene.get_drawables(True))
xy = cam.sample_pixel(4096)
rays_o, rays_d = cam.get_selected_rays(xy=xy)
pts = torch.randn([800, 3], dtype=torch.float, device=device) + cam.world_transform.translation()
ret = cam.project_pts_in_image(pts)
pts = cam.get_view_frustum_pts()
#--------------------- Multiple camera bundles + single frame ind
scene.slice_at(21)
cams: List[Camera] = scene.get_observer_groups_by_class_name('Camera', True).to_list()
cam_bundle = MultiCamBundle(cams)
cam_bundle.filter_drawable_groups(scene.get_drawables(True))
xy = cam_bundle.sample_pixel(4096)
rays_o, rays_d = cam_bundle.get_selected_rays(xy=xy)
ci = torch.randint(len(cams), (4096,), dtype=torch.long, device=device)
xy = torch.rand([4096, 2], dtype=torch.float, device=device)
rays_o, rays_d = cam_bundle.get_selected_rays(sel=ci, xy=xy)
pts = torch.randn([1, 800, 3], dtype=torch.float, device=device) + cams[0].world_transform.translation()
ret = cam_bundle.project_pts_in_image(pts)
unit_test()