Fix returning a proper rotation in levelling; supporting batches and default centroid

Summary:
`get_rotation_to_best_fit_xy` is useful to expose externally, however there was a bug (which we probably did not care about for our use case): it could return a rotation matrix with det(R) == −1.
The diff fixes that, and also makes centroid optional (it can be computed from points).

Reviewed By: bottler

Differential Revision: D39926791

fbshipit-source-id: 5120c7892815b829f3ddcc23e93d4a5ec0ca0013

pytorch3d/implicitron/tools/circle_fitting.py

@@ -12,22 +12,30 @@ from typing import Optional
 import torch
 
 
-def _get_rotation_to_best_fit_xy(
-    points: torch.Tensor, centroid: torch.Tensor
+def get_rotation_to_best_fit_xy(
+    points: torch.Tensor, centroid: Optional[torch.Tensor] = None
 ) -> torch.Tensor:
     """
-    Returns a rotation r such that points @ r has a best fit plane
+    Returns a rotation R such that `points @ R` has a best fit plane
     parallel to the xy plane
 
     Args:
-        points: (N, 3) tensor of points in 3D
-        centroid: (3,) their centroid
+        points: (*, N, 3) tensor of points in 3D
+        centroid: (*, 1, 3), (3,) or scalar: their centroid
 
     Returns:
-        (3,3) tensor rotation matrix
+        (*, 3, 3) tensor rotation matrix
     """
-    points_centered = points - centroid[None]
-    return torch.linalg.eigh(points_centered.t() @ points_centered)[1][:, [1, 2, 0]]
+    if centroid is None:
+        centroid = points.mean(dim=-2, keepdim=True)
+
+    points_centered = points - centroid
+    _, evec = torch.linalg.eigh(points_centered.transpose(-1, -2) @ points_centered)
+    # in general, evec can form either right- or left-handed basis,
+    # but we need the former to have a proper rotation (not reflection)
+    return torch.cat(
+        (evec[..., 1:], torch.cross(evec[..., 1], evec[..., 2])[..., None]), dim=-1
+    )
 
 
 def _signed_area(path: torch.Tensor) -> torch.Tensor:
@@ -191,7 +199,7 @@ def fit_circle_in_3d(
         Circle3D object
     """
     centroid = points.mean(0)
-    r = _get_rotation_to_best_fit_xy(points, centroid)
+    r = get_rotation_to_best_fit_xy(points, centroid)
     normal = r[:, 2]
     rotated_points = (points - centroid) @ r
     result_2d = fit_circle_in_2d(

tests/implicitron/test_circle_fitting.py

@@ -12,8 +12,9 @@ from pytorch3d.implicitron.tools.circle_fitting import (
     _signed_area,
     fit_circle_in_2d,
     fit_circle_in_3d,
+    get_rotation_to_best_fit_xy,
 )
-from pytorch3d.transforms import random_rotation
+from pytorch3d.transforms import random_rotation, random_rotations
 from tests.common_testing import TestCaseMixin
 
 
@@ -28,6 +29,32 @@ class TestCircleFitting(TestCaseMixin, unittest.TestCase):
         """
         self.assertClose(torch.cross(a, b, dim=-1), torch.zeros_like(a), **kwargs)
 
+    def test_plane_levelling(self):
+        device = torch.device("cuda:0")
+        B = 16
+        N = 1024
+        random = torch.randn((B, N, 3), device=device)
+
+        # first, check that we always return a vaild rotation
+        rot = get_rotation_to_best_fit_xy(random)
+        self.assertClose(rot.det(), torch.ones_like(rot[:, 0, 0]))
+        self.assertClose(rot.norm(dim=-1), torch.ones_like(rot[:, 0]))
+
+        # then, check the result is what we expect
+        z_squeeze = 0.1
+        random[..., -1] *= z_squeeze
+        rot_gt = random_rotations(B, device=device)
+        rotated = random @ rot_gt.transpose(-1, -2)
+        rot_hat = get_rotation_to_best_fit_xy(rotated)
+        self.assertClose(rot.det(), torch.ones_like(rot[:, 0, 0]))
+        self.assertClose(rot.norm(dim=-1), torch.ones_like(rot[:, 0]))
+        # covariance matrix of the levelled points is by design diag(1, 1, z_squeeze²)
+        self.assertClose(
+            (rotated @ rot_hat)[..., -1].std(dim=-1),
+            torch.ones_like(rot_hat[:, 0, 0]) * z_squeeze,
+            rtol=0.1,
+        )
+
     def test_simple_3d(self):
         device = torch.device("cuda:0")
         for _ in range(7):