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import torch |
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import numpy as np |
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_EPS4 = np.finfo(float).eps * 4.0 |
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_FLOAT_EPS = np.finfo(np.float64).eps |
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def qinv(q): |
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assert q.shape[-1] == 4, 'q must be a tensor of shape (*, 4)' |
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mask = torch.ones_like(q) |
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mask[..., 1:] = -mask[..., 1:] |
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return q * mask |
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def qinv_np(q): |
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assert q.shape[-1] == 4, 'q must be a tensor of shape (*, 4)' |
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return qinv(torch.from_numpy(q).float()).numpy() |
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def qnormalize(q): |
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assert q.shape[-1] == 4, 'q must be a tensor of shape (*, 4)' |
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return q / torch.norm(q, dim=-1, keepdim=True) |
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def qmul(q, r): |
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""" |
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Multiply quaternion(s) q with quaternion(s) r. |
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Expects two equally-sized tensors of shape (*, 4), where * denotes any number of dimensions. |
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Returns q*r as a tensor of shape (*, 4). |
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""" |
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assert q.shape[-1] == 4 |
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assert r.shape[-1] == 4 |
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original_shape = q.shape |
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terms = torch.bmm(r.view(-1, 4, 1), q.view(-1, 1, 4)) |
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w = terms[:, 0, 0] - terms[:, 1, 1] - terms[:, 2, 2] - terms[:, 3, 3] |
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x = terms[:, 0, 1] + terms[:, 1, 0] - terms[:, 2, 3] + terms[:, 3, 2] |
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y = terms[:, 0, 2] + terms[:, 1, 3] + terms[:, 2, 0] - terms[:, 3, 1] |
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z = terms[:, 0, 3] - terms[:, 1, 2] + terms[:, 2, 1] + terms[:, 3, 0] |
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return torch.stack((w, x, y, z), dim=1).view(original_shape) |
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def qrot(q, v): |
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""" |
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Rotate vector(s) v about the rotation described by quaternion(s) q. |
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Expects a tensor of shape (*, 4) for q and a tensor of shape (*, 3) for v, |
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where * denotes any number of dimensions. |
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Returns a tensor of shape (*, 3). |
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""" |
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assert q.shape[-1] == 4 |
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assert v.shape[-1] == 3 |
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assert q.shape[:-1] == v.shape[:-1] |
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original_shape = list(v.shape) |
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q = q.contiguous().view(-1, 4) |
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v = v.contiguous().view(-1, 3) |
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qvec = q[:, 1:] |
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uv = torch.cross(qvec, v, dim=1) |
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uuv = torch.cross(qvec, uv, dim=1) |
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return (v + 2 * (q[:, :1] * uv + uuv)).view(original_shape) |
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def qeuler(q, order, epsilon=0, deg=True): |
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""" |
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Convert quaternion(s) q to Euler angles. |
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Expects a tensor of shape (*, 4), where * denotes any number of dimensions. |
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Returns a tensor of shape (*, 3). |
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""" |
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assert q.shape[-1] == 4 |
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original_shape = list(q.shape) |
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original_shape[-1] = 3 |
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q = q.view(-1, 4) |
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q0 = q[:, 0] |
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q1 = q[:, 1] |
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q2 = q[:, 2] |
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q3 = q[:, 3] |
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if order == 'xyz': |
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x = torch.atan2(2 * (q0 * q1 - q2 * q3), 1 - 2 * (q1 * q1 + q2 * q2)) |
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y = torch.asin(torch.clamp(2 * (q1 * q3 + q0 * q2), -1 + epsilon, 1 - epsilon)) |
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z = torch.atan2(2 * (q0 * q3 - q1 * q2), 1 - 2 * (q2 * q2 + q3 * q3)) |
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elif order == 'yzx': |
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x = torch.atan2(2 * (q0 * q1 - q2 * q3), 1 - 2 * (q1 * q1 + q3 * q3)) |
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y = torch.atan2(2 * (q0 * q2 - q1 * q3), 1 - 2 * (q2 * q2 + q3 * q3)) |
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z = torch.asin(torch.clamp(2 * (q1 * q2 + q0 * q3), -1 + epsilon, 1 - epsilon)) |
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elif order == 'zxy': |
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x = torch.asin(torch.clamp(2 * (q0 * q1 + q2 * q3), -1 + epsilon, 1 - epsilon)) |
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y = torch.atan2(2 * (q0 * q2 - q1 * q3), 1 - 2 * (q1 * q1 + q2 * q2)) |
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z = torch.atan2(2 * (q0 * q3 - q1 * q2), 1 - 2 * (q1 * q1 + q3 * q3)) |
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elif order == 'xzy': |
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x = torch.atan2(2 * (q0 * q1 + q2 * q3), 1 - 2 * (q1 * q1 + q3 * q3)) |
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y = torch.atan2(2 * (q0 * q2 + q1 * q3), 1 - 2 * (q2 * q2 + q3 * q3)) |
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z = torch.asin(torch.clamp(2 * (q0 * q3 - q1 * q2), -1 + epsilon, 1 - epsilon)) |
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elif order == 'yxz': |
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x = torch.asin(torch.clamp(2 * (q0 * q1 - q2 * q3), -1 + epsilon, 1 - epsilon)) |
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y = torch.atan2(2 * (q1 * q3 + q0 * q2), 1 - 2 * (q1 * q1 + q2 * q2)) |
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z = torch.atan2(2 * (q1 * q2 + q0 * q3), 1 - 2 * (q1 * q1 + q3 * q3)) |
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elif order == 'zyx': |
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x = torch.atan2(2 * (q0 * q1 + q2 * q3), 1 - 2 * (q1 * q1 + q2 * q2)) |
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y = torch.asin(torch.clamp(2 * (q0 * q2 - q1 * q3), -1 + epsilon, 1 - epsilon)) |
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z = torch.atan2(2 * (q0 * q3 + q1 * q2), 1 - 2 * (q2 * q2 + q3 * q3)) |
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else: |
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raise |
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if deg: |
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return torch.stack((x, y, z), dim=1).view(original_shape) * 180 / np.pi |
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else: |
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return torch.stack((x, y, z), dim=1).view(original_shape) |
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def qmul_np(q, r): |
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q = torch.from_numpy(q).contiguous().float() |
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r = torch.from_numpy(r).contiguous().float() |
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return qmul(q, r).numpy() |
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def qrot_np(q, v): |
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q = torch.from_numpy(q).contiguous().float() |
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v = torch.from_numpy(v).contiguous().float() |
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return qrot(q, v).numpy() |
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def qeuler_np(q, order, epsilon=0, use_gpu=False): |
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if use_gpu: |
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q = torch.from_numpy(q).cuda().float() |
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return qeuler(q, order, epsilon).cpu().numpy() |
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else: |
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q = torch.from_numpy(q).contiguous().float() |
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return qeuler(q, order, epsilon).numpy() |
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def qfix(q): |
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""" |
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Enforce quaternion continuity across the time dimension by selecting |
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the representation (q or -q) with minimal distance (or, equivalently, maximal dot product) |
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between two consecutive frames. |
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Expects a tensor of shape (L, J, 4), where L is the sequence length and J is the number of joints. |
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Returns a tensor of the same shape. |
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""" |
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assert len(q.shape) == 3 |
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assert q.shape[-1] == 4 |
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result = q.copy() |
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dot_products = np.sum(q[1:] * q[:-1], axis=2) |
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mask = dot_products < 0 |
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mask = (np.cumsum(mask, axis=0) % 2).astype(bool) |
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result[1:][mask] *= -1 |
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return result |
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def euler2quat(e, order, deg=True): |
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""" |
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Convert Euler angles to quaternions. |
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""" |
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assert e.shape[-1] == 3 |
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original_shape = list(e.shape) |
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original_shape[-1] = 4 |
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e = e.view(-1, 3) |
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if deg: |
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e = e * np.pi / 180. |
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x = e[:, 0] |
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y = e[:, 1] |
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z = e[:, 2] |
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rx = torch.stack((torch.cos(x / 2), torch.sin(x / 2), torch.zeros_like(x), torch.zeros_like(x)), dim=1) |
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ry = torch.stack((torch.cos(y / 2), torch.zeros_like(y), torch.sin(y / 2), torch.zeros_like(y)), dim=1) |
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rz = torch.stack((torch.cos(z / 2), torch.zeros_like(z), torch.zeros_like(z), torch.sin(z / 2)), dim=1) |
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result = None |
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for coord in order: |
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if coord == 'x': |
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r = rx |
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elif coord == 'y': |
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r = ry |
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elif coord == 'z': |
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r = rz |
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else: |
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raise |
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if result is None: |
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result = r |
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else: |
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result = qmul(result, r) |
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if order in ['xyz', 'yzx', 'zxy']: |
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result *= -1 |
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return result.view(original_shape) |
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def expmap_to_quaternion(e): |
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""" |
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Convert axis-angle rotations (aka exponential maps) to quaternions. |
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Stable formula from "Practical Parameterization of Rotations Using the Exponential Map". |
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Expects a tensor of shape (*, 3), where * denotes any number of dimensions. |
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Returns a tensor of shape (*, 4). |
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""" |
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assert e.shape[-1] == 3 |
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original_shape = list(e.shape) |
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original_shape[-1] = 4 |
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e = e.reshape(-1, 3) |
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theta = np.linalg.norm(e, axis=1).reshape(-1, 1) |
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w = np.cos(0.5 * theta).reshape(-1, 1) |
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xyz = 0.5 * np.sinc(0.5 * theta / np.pi) * e |
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return np.concatenate((w, xyz), axis=1).reshape(original_shape) |
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def euler_to_quaternion(e, order): |
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""" |
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Convert Euler angles to quaternions. |
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""" |
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assert e.shape[-1] == 3 |
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original_shape = list(e.shape) |
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original_shape[-1] = 4 |
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e = e.reshape(-1, 3) |
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x = e[:, 0] |
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y = e[:, 1] |
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z = e[:, 2] |
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rx = np.stack((np.cos(x / 2), np.sin(x / 2), np.zeros_like(x), np.zeros_like(x)), axis=1) |
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ry = np.stack((np.cos(y / 2), np.zeros_like(y), np.sin(y / 2), np.zeros_like(y)), axis=1) |
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rz = np.stack((np.cos(z / 2), np.zeros_like(z), np.zeros_like(z), np.sin(z / 2)), axis=1) |
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result = None |
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for coord in order: |
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if coord == 'x': |
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r = rx |
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elif coord == 'y': |
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r = ry |
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elif coord == 'z': |
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r = rz |
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else: |
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raise |
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if result is None: |
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result = r |
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else: |
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result = qmul_np(result, r) |
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if order in ['xyz', 'yzx', 'zxy']: |
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result *= -1 |
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return result.reshape(original_shape) |
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def quaternion_to_matrix(quaternions): |
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""" |
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Convert rotations given as quaternions to rotation matrices. |
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Args: |
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quaternions: quaternions with real part first, |
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as tensor of shape (..., 4). |
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Returns: |
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Rotation matrices as tensor of shape (..., 3, 3). |
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""" |
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r, i, j, k = torch.unbind(quaternions, -1) |
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two_s = 2.0 / (quaternions * quaternions).sum(-1) |
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o = torch.stack( |
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( |
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1 - two_s * (j * j + k * k), |
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two_s * (i * j - k * r), |
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two_s * (i * k + j * r), |
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two_s * (i * j + k * r), |
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1 - two_s * (i * i + k * k), |
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two_s * (j * k - i * r), |
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two_s * (i * k - j * r), |
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two_s * (j * k + i * r), |
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1 - two_s * (i * i + j * j), |
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), |
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-1, |
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) |
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return o.reshape(quaternions.shape[:-1] + (3, 3)) |
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def quaternion_to_matrix_np(quaternions): |
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q = torch.from_numpy(quaternions).contiguous().float() |
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return quaternion_to_matrix(q).numpy() |
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def quaternion_to_cont6d_np(quaternions): |
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rotation_mat = quaternion_to_matrix_np(quaternions) |
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cont_6d = np.concatenate([rotation_mat[..., 0], rotation_mat[..., 1]], axis=-1) |
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return cont_6d |
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def quaternion_to_cont6d(quaternions): |
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rotation_mat = quaternion_to_matrix(quaternions) |
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cont_6d = torch.cat([rotation_mat[..., 0], rotation_mat[..., 1]], dim=-1) |
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return cont_6d |
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def cont6d_to_matrix(cont6d): |
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assert cont6d.shape[-1] == 6, "The last dimension must be 6" |
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x_raw = cont6d[..., 0:3] |
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y_raw = cont6d[..., 3:6] |
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x = x_raw / torch.norm(x_raw, dim=-1, keepdim=True) |
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z = torch.cross(x, y_raw, dim=-1) |
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z = z / torch.norm(z, dim=-1, keepdim=True) |
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y = torch.cross(z, x, dim=-1) |
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x = x[..., None] |
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y = y[..., None] |
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z = z[..., None] |
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mat = torch.cat([x, y, z], dim=-1) |
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return mat |
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def cont6d_to_matrix_np(cont6d): |
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q = torch.from_numpy(cont6d).contiguous().float() |
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return cont6d_to_matrix(q).numpy() |
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def qpow(q0, t, dtype=torch.float): |
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''' q0 : tensor of quaternions |
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t: tensor of powers |
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''' |
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q0 = qnormalize(q0) |
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theta0 = torch.acos(q0[..., 0]) |
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mask = (theta0 <= 10e-10) * (theta0 >= -10e-10) |
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theta0 = (1 - mask) * theta0 + mask * 10e-10 |
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v0 = q0[..., 1:] / torch.sin(theta0).view(-1, 1) |
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if isinstance(t, torch.Tensor): |
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q = torch.zeros(t.shape + q0.shape) |
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theta = t.view(-1, 1) * theta0.view(1, -1) |
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else: |
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q = torch.zeros(q0.shape) |
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theta = t * theta0 |
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q[..., 0] = torch.cos(theta) |
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q[..., 1:] = v0 * torch.sin(theta).unsqueeze(-1) |
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return q.to(dtype) |
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def qslerp(q0, q1, t): |
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''' |
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q0: starting quaternion |
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q1: ending quaternion |
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t: array of points along the way |
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Returns: |
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Tensor of Slerps: t.shape + q0.shape |
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''' |
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q0 = qnormalize(q0) |
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q1 = qnormalize(q1) |
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q_ = qpow(qmul(q1, qinv(q0)), t) |
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return qmul(q_, |
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q0.contiguous().view(torch.Size([1] * len(t.shape)) + q0.shape).expand(t.shape + q0.shape).contiguous()) |
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def qbetween(v0, v1): |
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''' |
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find the quaternion used to rotate v0 to v1 |
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''' |
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assert v0.shape[-1] == 3, 'v0 must be of the shape (*, 3)' |
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assert v1.shape[-1] == 3, 'v1 must be of the shape (*, 3)' |
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v = torch.cross(v0, v1) |
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w = torch.sqrt((v0 ** 2).sum(dim=-1, keepdim=True) * (v1 ** 2).sum(dim=-1, keepdim=True)) + (v0 * v1).sum(dim=-1, |
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keepdim=True) |
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return qnormalize(torch.cat([w, v], dim=-1)) |
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def qbetween_np(v0, v1): |
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''' |
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find the quaternion used to rotate v0 to v1 |
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''' |
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assert v0.shape[-1] == 3, 'v0 must be of the shape (*, 3)' |
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assert v1.shape[-1] == 3, 'v1 must be of the shape (*, 3)' |
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v0 = torch.from_numpy(v0).float() |
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v1 = torch.from_numpy(v1).float() |
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return qbetween(v0, v1).numpy() |
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def lerp(p0, p1, t): |
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if not isinstance(t, torch.Tensor): |
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t = torch.Tensor([t]) |
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new_shape = t.shape + p0.shape |
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new_view_t = t.shape + torch.Size([1] * len(p0.shape)) |
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new_view_p = torch.Size([1] * len(t.shape)) + p0.shape |
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p0 = p0.view(new_view_p).expand(new_shape) |
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p1 = p1.view(new_view_p).expand(new_shape) |
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t = t.view(new_view_t).expand(new_shape) |
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return p0 + t * (p1 - p0) |
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