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visualizer.py
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visualizer.py
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# %%
import argparse
import taichi as ti
from taichi_3d_gaussian_splatting.Camera import CameraInfo
from taichi_3d_gaussian_splatting.GaussianPointCloudRasterisation import GaussianPointCloudRasterisation
from taichi_3d_gaussian_splatting.GaussianPointCloudScene import GaussianPointCloudScene
from taichi_3d_gaussian_splatting.utils import torch2ti, SE3_to_quaternion_and_translation_torch, quaternion_rotate_torch, quaternion_multiply_torch, quaternion_conjugate_torch
from dataclasses import dataclass
from typing import List, Tuple
import torch
import numpy as np
from scipy.spatial.transform import Rotation as R
# %%
@ti.kernel
def torchImage2tiImage(field: ti.template(), data: ti.types.ndarray()):
for row, col in ti.ndrange(data.shape[0], data.shape[1]):
field[col, data.shape[0] - row -
1] = ti.math.vec3(data[row, col, 0], data[row, col, 1], data[row, col, 2])
class GaussianPointVisualizer:
@dataclass
class GaussianPointVisualizerConfig:
device: str = "cuda"
image_height: int = 546
image_width: int = 980
camera_intrinsics: torch.Tensor = torch.tensor(
[[581.743, 0.0, 490.0], [0.0, 581.743, 273.0], [0.0, 0.0, 1.0]],
device="cuda")
initial_T_pointcloud_camera: torch.Tensor = torch.tensor(
[[0.9992602094, -0.0041446825, 0.0382342376, 0.8111615373], [0.0047891027, 0.9998477637, -0.0167783848,
0.4972433596], [-0.0381588759, 0.0169490798, 0.999127935, -3.8378280443], [0.0, 0.0, 0.0, 1.0]],
device="cuda")
parquet_path_list: List[str] = None
step_size: float = 0.1
mouse_sensitivity: float = 3
@dataclass
class GaussianPointVisualizerState:
next_t_pointcloud_camera: torch.Tensor
next_q_pointcloud_camera: torch.Tensor
selected_scene: int = 0
last_mouse_pos: Tuple[float, float] = None
@dataclass
class ExtraSceneInfo:
start_offset: int
end_offset: int
center: torch.Tensor
visible: bool
def __init__(self, config) -> None:
self.config = config
self.config.image_height = self.config.image_height - self.config.image_height % 16
self.config.image_width = self.config.image_width - self.config.image_width % 16
scene_list = []
for parquet_path in self.config.parquet_path_list:
print(f"Loading {parquet_path}")
scene = GaussianPointCloudScene.from_parquet(
parquet_path, config=GaussianPointCloudScene.PointCloudSceneConfig(max_num_points_ratio=None))
scene_list.append(scene)
print("Merging scenes")
self.scene = self._merge_scenes(scene_list)
print("Done merging scenes")
self.scene = self.scene.to(self.config.device)
initial_T_pointcloud_camera = self.config.initial_T_pointcloud_camera.to(
self.config.device)
initial_T_pointcloud_camera = initial_T_pointcloud_camera.unsqueeze(
0).repeat(len(scene_list), 1, 1)
initial_q_pointcloud_camera, initial_t_pointcloud_camera = SE3_to_quaternion_and_translation_torch(
initial_T_pointcloud_camera)
self.state = self.GaussianPointVisualizerState(
next_q_pointcloud_camera=initial_q_pointcloud_camera,
next_t_pointcloud_camera=initial_t_pointcloud_camera,
selected_scene=0,
last_mouse_pos=None,
)
self.gui = ti.GUI(
"Gaussian Point Visualizer",
(self.config.image_width, self.config.image_height),
fast_gui=True)
self.camera_info = CameraInfo(
camera_intrinsics=self.config.camera_intrinsics.to(
self.config.device),
camera_width=self.config.image_width,
camera_height=self.config.image_height,
camera_id=0,
)
self.rasteriser = GaussianPointCloudRasterisation(
config=GaussianPointCloudRasterisation.GaussianPointCloudRasterisationConfig(
near_plane=0.8,
far_plane=1000.,
depth_to_sort_key_scale=100.))
self.image_buffer = ti.Vector.field(3, dtype=ti.f32, shape=(
self.config.image_width, self.config.image_height))
def start(self):
while self.gui.running:
events = self.gui.get_events(self.gui.PRESS)
start_offset = 0
end_offset = self.scene.point_cloud.shape[0]
selected_objects = torch.arange(
len(self.extra_scene_info_dict), device=self.config.device)
object_selected = self.state.selected_scene != 0
move_factor = -1 if object_selected else 1
if object_selected:
start_offset = self.extra_scene_info_dict[self.state.selected_scene - 1].start_offset
end_offset = self.extra_scene_info_dict[self.state.selected_scene - 1].end_offset
selected_objects = self.state.selected_scene - 1
for event in events:
if event.key >= "0" and event.key <= "9":
scene_index = int(event.key)
if scene_index <= len(self.extra_scene_info_dict):
self.state.selected_scene = scene_index
elif event.key == "w":
delta = torch.zeros_like(
self.state.next_t_pointcloud_camera)
delta[selected_objects,
2] = self.config.step_size * move_factor
delta = quaternion_rotate_torch(
v=delta, q=self.state.next_q_pointcloud_camera)
self.state.next_t_pointcloud_camera += delta
elif event.key == "s":
delta = torch.zeros_like(
self.state.next_t_pointcloud_camera)
delta[selected_objects, 2] = - \
self.config.step_size * move_factor
delta = quaternion_rotate_torch(
v=delta, q=self.state.next_q_pointcloud_camera)
self.state.next_t_pointcloud_camera += delta
elif event.key == "a":
delta = torch.zeros_like(
self.state.next_t_pointcloud_camera)
delta[selected_objects, 0] = - \
self.config.step_size * move_factor
delta = quaternion_rotate_torch(
v=delta, q=self.state.next_q_pointcloud_camera)
self.state.next_t_pointcloud_camera += delta
elif event.key == "d":
delta = torch.zeros_like(
self.state.next_t_pointcloud_camera)
delta[selected_objects,
0] = self.config.step_size * move_factor
delta = quaternion_rotate_torch(
v=delta, q=self.state.next_q_pointcloud_camera)
self.state.next_t_pointcloud_camera += delta
elif event.key == "-":
delta = torch.zeros_like(
self.state.next_t_pointcloud_camera)
delta[selected_objects,
1] = self.config.step_size * move_factor
delta = quaternion_rotate_torch(
v=delta, q=self.state.next_q_pointcloud_camera)
self.state.next_t_pointcloud_camera += delta
elif event.key == "=":
delta = torch.zeros_like(
self.state.next_t_pointcloud_camera)
delta[selected_objects, 1] = - \
self.config.step_size * move_factor
delta = quaternion_rotate_torch(
v=delta, q=self.state.next_q_pointcloud_camera)
self.state.next_t_pointcloud_camera += delta
elif event.key == "q":
delta_q = torch.zeros_like(
self.state.next_q_pointcloud_camera)
delta_q[..., 3] = 1.
delta_q[selected_objects,
3] = np.cos(-self.config.step_size / 2 * move_factor)
delta_q[selected_objects,
1] = np.sin(-self.config.step_size / 2 * move_factor)
delta_q = delta_q / \
torch.norm(delta_q, dim=-1, keepdim=True)
self.state.next_q_pointcloud_camera = quaternion_multiply_torch(
self.state.next_q_pointcloud_camera, delta_q)
self.state.next_q_pointcloud_camera = self.state.next_q_pointcloud_camera / \
torch.norm(self.state.next_q_pointcloud_camera,
dim=-1, keepdim=True)
elif event.key == "e":
delta_q = torch.zeros_like(
self.state.next_q_pointcloud_camera)
delta_q[..., 3] = 1.
delta_q[selected_objects, 3] = np.cos(
self.config.step_size / 2 * move_factor)
delta_q[selected_objects, 1] = np.sin(
self.config.step_size / 2 * move_factor)
delta_q = delta_q / \
torch.norm(delta_q, dim=-1, keepdim=True)
self.state.next_q_pointcloud_camera = quaternion_multiply_torch(
self.state.next_q_pointcloud_camera, delta_q)
self.state.next_q_pointcloud_camera = self.state.next_q_pointcloud_camera / \
torch.norm(self.state.next_q_pointcloud_camera,
dim=-1, keepdim=True)
elif event.key == "h":
self.scene.point_invalid_mask[start_offset:end_offset] = 1
elif event.key == "p":
self.scene.point_invalid_mask[start_offset:end_offset] = 0
mouse_pos = self.gui.get_cursor_pos()
if self.gui.is_pressed(self.gui.LMB):
if self.state.last_mouse_pos is None:
self.state.last_mouse_pos = mouse_pos
else:
dy, dx = mouse_pos[0] - self.state.last_mouse_pos[0], mouse_pos[1] - \
self.state.last_mouse_pos[1]
angle_x = dx * self.config.mouse_sensitivity
angle_y = dy * self.config.mouse_sensitivity
if self.state.selected_scene != 0:
pointcloud_object_center = self.extra_scene_info_dict[self.state.selected_scene - 1].center.unsqueeze(
0)
pointcloud_object_center = pointcloud_object_center.to(
self.state.next_t_pointcloud_camera.device)
pointcloud_camera_to_center = pointcloud_object_center - \
self.state.next_t_pointcloud_camera[selected_objects]
camera_camera_to_center = quaternion_rotate_torch(
q=quaternion_conjugate_torch(
self.state.next_q_pointcloud_camera[selected_objects]),
v=pointcloud_camera_to_center)
delta_q_y = torch.zeros_like(
self.state.next_q_pointcloud_camera)
delta_q_y[..., 3] = 1.
delta_q_y[selected_objects, 3] = np.cos(angle_y / 2)
delta_q_y[selected_objects, 1] = np.sin(angle_y / 2)
delta_q_y = delta_q_y / \
torch.norm(delta_q_y, dim=-1, keepdim=True)
self.state.next_q_pointcloud_camera = quaternion_multiply_torch(
self.state.next_q_pointcloud_camera, delta_q_y)
self.state.next_q_pointcloud_camera = self.state.next_q_pointcloud_camera / \
torch.norm(self.state.next_q_pointcloud_camera,
dim=-1, keepdim=True)
delta_q_x = torch.zeros_like(
self.state.next_q_pointcloud_camera)
delta_q_x[..., 3] = 1.
delta_q_x[selected_objects, 3] = np.cos(angle_x / 2)
delta_q_x[selected_objects, 0] = np.sin(angle_x / 2)
delta_q_x = delta_q_x / \
torch.norm(delta_q_x, dim=-1, keepdim=True)
self.state.next_q_pointcloud_camera = quaternion_multiply_torch(
self.state.next_q_pointcloud_camera, delta_q_x)
self.state.next_q_pointcloud_camera = self.state.next_q_pointcloud_camera / \
torch.norm(self.state.next_q_pointcloud_camera,
dim=-1, keepdim=True)
if object_selected:
pointcloud_object_center = self.extra_scene_info_dict[self.state.selected_scene - 1].center.unsqueeze(
0)
pointcloud_object_center = pointcloud_object_center.to(
self.state.next_t_pointcloud_camera.device)
object_center_new = quaternion_rotate_torch(
q=self.state.next_q_pointcloud_camera[selected_objects],
v=camera_camera_to_center)
self.state.next_t_pointcloud_camera[selected_objects] = pointcloud_object_center - object_center_new
self.state.last_mouse_pos = mouse_pos
else:
self.state.last_mouse_pos = None
with torch.no_grad():
image, _, _ = self.rasteriser(
GaussianPointCloudRasterisation.GaussianPointCloudRasterisationInput(
point_cloud=self.scene.point_cloud,
point_cloud_features=self.scene.point_cloud_features,
point_invalid_mask=self.scene.point_invalid_mask,
point_object_id=self.scene.point_object_id,
camera_info=self.camera_info,
q_pointcloud_camera=self.state.next_q_pointcloud_camera,
t_pointcloud_camera=self.state.next_t_pointcloud_camera,
color_max_sh_band=3,
)
)
# ti.profiler.print_kernel_profiler_info("count")
# ti.profiler.clear_kernel_profiler_info()
torchImage2tiImage(self.image_buffer, image)
self.gui.set_image(self.image_buffer)
self.gui.show()
self.gui.close()
def _merge_scenes(self, scene_list):
# the config does not matter here, only for training
merged_point_cloud = torch.cat(
[scene.point_cloud for scene in scene_list], dim=0)
merged_point_cloud_features = torch.cat(
[scene.point_cloud_features for scene in scene_list], dim=0)
num_of_points_list = [scene.point_cloud.shape[0]
for scene in scene_list]
start_offset_list = [0] + np.cumsum(num_of_points_list).tolist()[:-1]
end_offset_list = np.cumsum(num_of_points_list).tolist()
self.extra_scene_info_dict = {
idx: self.ExtraSceneInfo(
start_offset=start_offset,
end_offset=end_offset,
center=scene_list[idx].point_cloud.mean(dim=0),
visible=True
) for idx, (start_offset, end_offset) in enumerate(zip(start_offset_list, end_offset_list))
}
point_object_id = torch.zeros(
(merged_point_cloud.shape[0],), dtype=torch.int32, device=self.config.device)
for idx, (start_offset, end_offset) in enumerate(zip(start_offset_list, end_offset_list)):
point_object_id[start_offset:end_offset] = idx
merged_scene = GaussianPointCloudScene(
point_cloud=merged_point_cloud,
point_cloud_features=merged_point_cloud_features,
point_object_id=point_object_id,
config=GaussianPointCloudScene.PointCloudSceneConfig(
max_num_points_ratio=None
))
return merged_scene
# %%
if __name__ == "__main__":
parser = argparse.ArgumentParser()
parser.add_argument("--parquet_path_list", type=str,
nargs="+", required=True)
args = parser.parse_args()
parquet_path_list = args.parquet_path_list
ti.init(arch=ti.cuda, device_memory_GB=4, kernel_profiler=True)
visualizer = GaussianPointVisualizer(config=GaussianPointVisualizer.GaussianPointVisualizerConfig(
parquet_path_list=parquet_path_list,
))
visualizer.start()