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base: hofee:2af52c64e26fa77a30b1eae7ecc9457185def23e
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hofee:master
hofee:ab_new_partial_global
hofee:new_partial_global
hofee:ab_global_only
hofee:hemisphere_random
hofee:ab_global_and_partial_global
hofee:ab_global_and_local
hofee:ab_local_only
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compare: hofee:60c935749146471c3a5dc0c4fd9523b0ddc63843
Branches Tags
hofee:ab_new_partial_global
hofee:new_partial_global
hofee:ab_global_only
hofee:hemisphere_random
hofee:master
hofee:ab_global_and_partial_global
hofee:ab_global_and_local
hofee:ab_local_only

3 Commits
2af52c64e2 ... 60c9357491

Author SHA1 Message Date
hofee
60c9357491 solve merge conflicts 2024-10-05 15:12:55 -05:00
hofee
11d460bd9b Merge branch 'master' of https://git.hofee.top/hofee/nbv_reconstruction 2024-10-05 15:11:01 -05:00
hofee
bb9b3f81c3 update reconstruction 2024-10-05 15:10:31 -05:00
4 changed files with 62 additions and 54 deletions
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4
configs/local/strategy_generate_config.yaml
View File

@ -28,8 +28,8 @@ runner:
datasets:
OmniObject3d:
#"/media/hofee/data/data/temp_output"
root_dir: "/media/hofee/repository/new_full_box_data"
model_dir: "/media/hofee/data/data/scaled_object_meshes"
root_dir: "C:\\Document\\Local Project\\nbv_rec\\nbv_reconstruction\\test\\test_sample"
model_dir: "H:\\AI\\Datasets\\scaled_object_meshes"
from: 0
to: -1 # -1 means end
#output_dir: "/media/hofee/data/data/label_output"

2
preprocess/preprocessor.py
View File

@ -155,7 +155,7 @@ if __name__ == "__main__":
total = to_idx - from_idx
for scene in scene_list[from_idx:to_idx]:
start = time.time()
save_scene_data(root, scene, cnt, total, "npy")
save_scene_data(root, scene, cnt, total, file_type="npy")
cnt+=1
end = time.time()
print(f"Time cost: {end-start}")

25
runners/strategy_generator.py
View File

@ -84,27 +84,38 @@ class StrategyGenerator(Runner):
pts_list = []
scan_points_indices_list = []
non_zero_cnt = 0
for frame_idx in range(frame_num):
status_manager.set_progress("generate_strategy", "strategy_generator", "loading frame", frame_idx, frame_num)
pts_path = os.path.join(root,scene_name, "target_pts", f"{frame_idx}.txt")
sampled_point_cloud = np.loadtxt(pts_path)
indices = None # ReconstructionUtil.compute_covered_scan_points(scan_points, display_table_pts)
pts_path = os.path.join(root,scene_name, "pts", f"{frame_idx}.npy")
idx_path = os.path.join(root,scene_name, "scan_points_indices", f"{frame_idx}.npy")
point_cloud = np.load(pts_path)
sampled_point_cloud = PtsUtil.voxel_downsample_point_cloud(point_cloud, voxel_threshold)
indices = np.load(idx_path)
pts_list.append(sampled_point_cloud)
scan_points_indices_list.append(indices)
if sampled_point_cloud.shape[0] > 0:
non_zero_cnt += 1
status_manager.set_progress("generate_strategy", "strategy_generator", "loading frame", frame_num, frame_num)
seq_num = min(self.seq_num, non_zero_cnt)
init_view_list = []
for i in range(seq_num):
if pts_list[i].shape[0] < 100:
continue
init_view_list.append(i)
idx = 0
while len(init_view_list) < seq_num:
if pts_list[idx].shape[0] > 100:
init_view_list.append(idx)
idx += 1
seq_idx = 0
import time
for init_view in init_view_list:
status_manager.set_progress("generate_strategy", "strategy_generator", "computing sequence", seq_idx, len(init_view_list))
start = time.time()
limited_useful_view, _, _ = ReconstructionUtil.compute_next_best_view_sequence_with_overlap(down_sampled_model_pts, pts_list, scan_points_indices_list = scan_points_indices_list,init_view=init_view,
threshold=voxel_threshold, soft_overlap_threshold=soft_overlap_threshold, hard_overlap_threshold= hard_overlap_threshold, scan_points_threshold=10, status_info=self.status_info)
end = time.time()
print(f"Time: {end-start}")
data_pairs = self.generate_data_pairs(limited_useful_view)
seq_save_data = {
"data_pairs": data_pairs,

77
utils/reconstruction.py
View File

@ -23,28 +23,6 @@ class ReconstructionUtil:
overlap_rate = overlapping_points / new_point_cloud.shape[0]
return overlap_rate
@staticmethod
def combine_point_with_view_sequence(point_list, view_sequence):
selected_views = []
for view_index, _ in view_sequence:
selected_views.append(point_list[view_index])
return np.vstack(selected_views)
@staticmethod
def compute_next_view_coverage_list(views, combined_point_cloud, target_point_cloud, threshold=0.01):
best_view = None
best_coverage_increase = -1
current_coverage = ReconstructionUtil.compute_coverage_rate(target_point_cloud, combined_point_cloud, threshold)
for view_index, view in enumerate(views):
candidate_views = combined_point_cloud + [view]
down_sampled_combined_point_cloud = PtsUtil.voxel_downsample_point_cloud(candidate_views, threshold)
new_coverage = ReconstructionUtil.compute_coverage_rate(target_point_cloud, down_sampled_combined_point_cloud, threshold)
coverage_increase = new_coverage - current_coverage
if coverage_increase > best_coverage_increase:
best_coverage_increase = coverage_increase
best_view = view_index
return best_view, best_coverage_increase
@staticmethod
def get_new_added_points(old_combined_pts, new_pts, threshold=0.005):
@ -60,54 +38,70 @@ class ReconstructionUtil:
@staticmethod
def compute_next_best_view_sequence_with_overlap(target_point_cloud, point_cloud_list, scan_points_indices_list, threshold=0.01, soft_overlap_threshold=0.5, hard_overlap_threshold=0.7, init_view = 0, scan_points_threshold=5, status_info=None):
selected_views = [point_cloud_list[init_view]]
combined_point_cloud = np.vstack(selected_views)
selected_views = [init_view]
combined_point_cloud = point_cloud_list[init_view]
history_indices = [scan_points_indices_list[init_view]]
down_sampled_combined_point_cloud = PtsUtil.voxel_downsample_point_cloud(combined_point_cloud,threshold)
new_coverage = ReconstructionUtil.compute_coverage_rate(target_point_cloud, down_sampled_combined_point_cloud, threshold)
max_rec_pts = np.vstack(point_cloud_list)
downsampled_max_rec_pts = PtsUtil.voxel_downsample_point_cloud(max_rec_pts, threshold)
max_rec_pts_num = downsampled_max_rec_pts.shape[0]
max_rec_pts_coverage = ReconstructionUtil.compute_coverage_rate(target_point_cloud, downsampled_max_rec_pts, threshold)
new_coverage = ReconstructionUtil.compute_coverage_rate(downsampled_max_rec_pts, combined_point_cloud, threshold)
current_coverage = new_coverage
remaining_views = list(range(len(point_cloud_list)))
view_sequence = [(init_view, current_coverage)]
cnt_processed_view = 0
remaining_views.remove(init_view)
curr_rec_pts_num = combined_point_cloud.shape[0]
import time
while remaining_views:
best_view = None
best_coverage_increase = -1
best_combined_point_cloud = None
for view_index in remaining_views:
if point_cloud_list[view_index].shape[0] == 0:
continue
if selected_views:
new_scan_points_indices = scan_points_indices_list[view_index]
if not ReconstructionUtil.check_scan_points_overlap(history_indices, new_scan_points_indices, scan_points_threshold):
overlap_threshold = hard_overlap_threshold
else:
overlap_threshold = soft_overlap_threshold
combined_old_point_cloud = np.vstack(selected_views)
down_sampled_old_point_cloud = PtsUtil.voxel_downsample_point_cloud(combined_old_point_cloud,threshold)
down_sampled_new_view_point_cloud = PtsUtil.voxel_downsample_point_cloud(point_cloud_list[view_index],threshold)
overlap_rate = ReconstructionUtil.compute_overlap_rate(down_sampled_new_view_point_cloud,down_sampled_old_point_cloud, threshold)
start = time.time()
overlap_rate = ReconstructionUtil.compute_overlap_rate(point_cloud_list[view_index],combined_point_cloud, threshold)
end = time.time()
# print(f"overlap_rate Time: {end-start}")
if overlap_rate < overlap_threshold:
continue
candidate_views = selected_views + [point_cloud_list[view_index]]
combined_point_cloud = np.vstack(candidate_views)
down_sampled_combined_point_cloud = PtsUtil.voxel_downsample_point_cloud(combined_point_cloud,threshold)
new_coverage = ReconstructionUtil.compute_coverage_rate(target_point_cloud, down_sampled_combined_point_cloud, threshold)
start = time.time()
new_combined_point_cloud = np.vstack([combined_point_cloud, point_cloud_list[view_index]])
new_downsampled_combined_point_cloud = PtsUtil.voxel_downsample_point_cloud(new_combined_point_cloud,threshold)
new_coverage = ReconstructionUtil.compute_coverage_rate(downsampled_max_rec_pts, new_downsampled_combined_point_cloud, threshold)
end = time.time()
#print(f"compute_coverage_rate Time: {end-start}")
coverage_increase = new_coverage - current_coverage
if coverage_increase > best_coverage_increase:
best_coverage_increase = coverage_increase
best_view = view_index
best_combined_point_cloud = new_downsampled_combined_point_cloud
if best_view is not None:
if best_coverage_increase <=3e-3:
if best_coverage_increase <=1e-3:
break
selected_views.append(point_cloud_list[best_view])
selected_views.append(best_view)
best_rec_pts_num = best_combined_point_cloud.shape[0]
print(f"Current rec pts num: {curr_rec_pts_num}, Best rec pts num: {best_rec_pts_num}, Max rec pts num: {max_rec_pts_num}")
print(f"Current coverage: {current_coverage}, Best coverage increase: {best_coverage_increase}, Max coverage: {max_rec_pts_coverage}")
curr_rec_pts_num = best_rec_pts_num
combined_point_cloud = best_combined_point_cloud
remaining_views.remove(best_view)
history_indices.append(scan_points_indices_list[best_view])
current_coverage += best_coverage_increase
@ -123,12 +117,15 @@ class ReconstructionUtil:
else:
break
# ----- Debug Trace ----- #
import ipdb; ipdb.set_trace()
# ------------------------ #
if status_info is not None:
sm = status_info["status_manager"]
app_name = status_info["app_name"]
runner_name = status_info["runner_name"]
sm.set_progress(app_name, runner_name, "processed view", len(point_cloud_list), len(point_cloud_list))
return view_sequence, remaining_views, down_sampled_combined_point_cloud
return view_sequence, remaining_views, combined_point_cloud
@staticmethod