assertion reports offense; fixed seeds for spherical and fiber
This commit is contained in:
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@ -461,7 +461,7 @@ def mul(me, other):
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if other.shape == (3,):
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if other.shape == (3,):
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A = me.quaternion[0]**2.0 - np.dot(me.quaternion[1:],me.quaternion[1:])
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A = me.quaternion[0]**2.0 - np.dot(me.quaternion[1:],me.quaternion[1:])
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B = 2.0 * np.dot(me.quaternion[1:],other)
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B = 2.0 * np.dot(me.quaternion[1:],other)
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C = 2.0 * _P*me.quaternion[0]
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C = 2.0 * _P * me.quaternion[0]
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return A*other + B*me.quaternion[1:] + C * np.cross(me.quaternion[1:],other)
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return A*other + B*me.quaternion[1:] + C * np.cross(me.quaternion[1:],other)
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@ -496,9 +496,8 @@ class TestRotation:
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o = backward(forward(m))
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o = backward(forward(m))
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ok = np.allclose(m,o,atol=atol)
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ok = np.allclose(m,o,atol=atol)
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if np.isclose(rot.as_quaternion()[0],0.0,atol=atol):
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if np.isclose(rot.as_quaternion()[0],0.0,atol=atol):
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ok = ok or np.allclose(m*-1.,o,atol=atol)
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ok |= np.allclose(m*-1.,o,atol=atol)
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print(m,o,rot.as_quaternion())
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assert ok and np.isclose(np.linalg.norm(o),1.0), f'{m},{o},{rot.as_quaternion()}'
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assert ok and np.isclose(np.linalg.norm(o),1.0)
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@pytest.mark.parametrize('forward,backward',[(Rotation._om2qu,Rotation._qu2om),
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@pytest.mark.parametrize('forward,backward',[(Rotation._om2qu,Rotation._qu2om),
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(Rotation._om2eu,Rotation._eu2om),
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(Rotation._om2eu,Rotation._eu2om),
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@ -512,8 +511,7 @@ class TestRotation:
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m = rot.as_matrix()
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m = rot.as_matrix()
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o = backward(forward(m))
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o = backward(forward(m))
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ok = np.allclose(m,o,atol=atol)
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ok = np.allclose(m,o,atol=atol)
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print(m,o,rot.as_quaternion())
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assert ok and np.isclose(np.linalg.det(o),1.0), f'{m},{o},{rot.as_quaternion()}'
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assert ok and np.isclose(np.linalg.det(o),1.0)
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@pytest.mark.parametrize('forward,backward',[(Rotation._eu2qu,Rotation._qu2eu),
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@pytest.mark.parametrize('forward,backward',[(Rotation._eu2qu,Rotation._qu2eu),
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(Rotation._eu2om,Rotation._om2eu),
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(Rotation._eu2om,Rotation._om2eu),
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@ -531,9 +529,9 @@ class TestRotation:
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ok = ok or np.allclose(np.where(np.isclose(m,u),m-u,m),np.where(np.isclose(o,u),o-u,o),atol=atol)
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ok = ok or np.allclose(np.where(np.isclose(m,u),m-u,m),np.where(np.isclose(o,u),o-u,o),atol=atol)
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if np.isclose(m[1],0.0,atol=atol) or np.isclose(m[1],np.pi,atol=atol):
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if np.isclose(m[1],0.0,atol=atol) or np.isclose(m[1],np.pi,atol=atol):
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sum_phi = np.unwrap([m[0]+m[2],o[0]+o[2]])
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sum_phi = np.unwrap([m[0]+m[2],o[0]+o[2]])
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ok = ok or np.isclose(sum_phi[0],sum_phi[1],atol=atol)
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ok |= np.isclose(sum_phi[0],sum_phi[1],atol=atol)
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print(m,o,rot.as_quaternion())
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assert ok and (np.zeros(3)-1.e-9 <= o).all() \
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assert ok and (np.zeros(3)-1.e-9 <= o).all() and (o <= np.array([np.pi*2.,np.pi,np.pi*2.])+1.e-9).all()
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and (o <= np.array([np.pi*2.,np.pi,np.pi*2.])+1.e-9).all(), f'{m},{o},{rot.as_quaternion()}'
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@pytest.mark.parametrize('forward,backward',[(Rotation._ax2qu,Rotation._qu2ax),
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@pytest.mark.parametrize('forward,backward',[(Rotation._ax2qu,Rotation._qu2ax),
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(Rotation._ax2om,Rotation._om2ax),
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(Rotation._ax2om,Rotation._om2ax),
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@ -548,9 +546,8 @@ class TestRotation:
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o = backward(forward(m))
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o = backward(forward(m))
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ok = np.allclose(m,o,atol=atol)
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ok = np.allclose(m,o,atol=atol)
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if np.isclose(m[3],np.pi,atol=atol):
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if np.isclose(m[3],np.pi,atol=atol):
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ok = ok or np.allclose(m*np.array([-1.,-1.,-1.,1.]),o,atol=atol)
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ok |= np.allclose(m*np.array([-1.,-1.,-1.,1.]),o,atol=atol)
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print(m,o,rot.as_quaternion())
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assert ok and np.isclose(np.linalg.norm(o[:3]),1.0) and o[3]<=np.pi+1.e-9, f'{m},{o},{rot.as_quaternion()}'
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assert ok and np.isclose(np.linalg.norm(o[:3]),1.0) and o[3]<=np.pi+1.e-9
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@pytest.mark.parametrize('forward,backward',[(Rotation._ro2qu,Rotation._qu2ro),
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@pytest.mark.parametrize('forward,backward',[(Rotation._ro2qu,Rotation._qu2ro),
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#(Rotation._ro2om,Rotation._om2ro),
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#(Rotation._ro2om,Rotation._om2ro),
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@ -566,8 +563,7 @@ class TestRotation:
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o = backward(forward(m))
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o = backward(forward(m))
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ok = np.allclose(np.clip(m,None,cutoff),np.clip(o,None,cutoff),atol=atol)
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ok = np.allclose(np.clip(m,None,cutoff),np.clip(o,None,cutoff),atol=atol)
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ok = ok or np.isclose(m[3],0.0,atol=atol)
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ok = ok or np.isclose(m[3],0.0,atol=atol)
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print(m,o,rot.as_quaternion())
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assert ok and np.isclose(np.linalg.norm(o[:3]),1.0), f'{m},{o},{rot.as_quaternion()}'
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assert ok and np.isclose(np.linalg.norm(o[:3]),1.0)
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@pytest.mark.parametrize('forward,backward',[(Rotation._ho2qu,Rotation._qu2ho),
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@pytest.mark.parametrize('forward,backward',[(Rotation._ho2qu,Rotation._qu2ho),
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(Rotation._ho2om,Rotation._om2ho),
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(Rotation._ho2om,Rotation._om2ho),
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@ -581,8 +577,7 @@ class TestRotation:
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m = rot.as_homochoric()
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m = rot.as_homochoric()
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o = backward(forward(m))
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o = backward(forward(m))
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ok = np.allclose(m,o,atol=atol)
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ok = np.allclose(m,o,atol=atol)
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print(m,o,rot.as_quaternion())
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assert ok and np.linalg.norm(o) < _R1 + 1.e-9, f'{m},{o},{rot.as_quaternion()}'
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assert ok and np.linalg.norm(o) < _R1 + 1.e-9
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@pytest.mark.parametrize('forward,backward',[(Rotation._cu2qu,Rotation._qu2cu),
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@pytest.mark.parametrize('forward,backward',[(Rotation._cu2qu,Rotation._qu2cu),
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(Rotation._cu2om,Rotation._om2cu),
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(Rotation._cu2om,Rotation._om2cu),
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@ -598,8 +593,7 @@ class TestRotation:
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ok = np.allclose(m,o,atol=atol)
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ok = np.allclose(m,o,atol=atol)
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if np.count_nonzero(np.isclose(np.abs(o),np.pi**(2./3.)*.5)):
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if np.count_nonzero(np.isclose(np.abs(o),np.pi**(2./3.)*.5)):
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ok = ok or np.allclose(m*-1.,o,atol=atol)
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ok = ok or np.allclose(m*-1.,o,atol=atol)
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print(m,o,rot.as_quaternion())
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assert ok and np.max(np.abs(o)) < np.pi**(2./3.) * 0.5 + 1.e-9, f'{m},{o},{rot.as_quaternion()}'
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assert ok and np.max(np.abs(o)) < np.pi**(2./3.) * 0.5 + 1.e-9
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@pytest.mark.parametrize('vectorized, single',[(Rotation._qu2om,qu2om),
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@pytest.mark.parametrize('vectorized, single',[(Rotation._qu2om,qu2om),
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(Rotation._qu2eu,qu2eu),
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(Rotation._qu2eu,qu2eu),
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@ -612,8 +606,7 @@ class TestRotation:
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vectorized(qu.reshape(qu.shape[0]//2,-1,4))
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vectorized(qu.reshape(qu.shape[0]//2,-1,4))
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co = vectorized(qu)
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co = vectorized(qu)
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for q,c in zip(qu,co):
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for q,c in zip(qu,co):
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print(q,c)
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assert np.allclose(single(q),c) and np.allclose(single(q),vectorized(q)), f'{q},{c}'
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assert np.allclose(single(q),c) and np.allclose(single(q),vectorized(q))
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@pytest.mark.parametrize('vectorized, single',[(Rotation._om2qu,om2qu),
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@pytest.mark.parametrize('vectorized, single',[(Rotation._om2qu,om2qu),
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@ -625,8 +618,7 @@ class TestRotation:
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vectorized(om.reshape(om.shape[0]//2,-1,3,3))
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vectorized(om.reshape(om.shape[0]//2,-1,3,3))
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co = vectorized(om)
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co = vectorized(om)
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for o,c in zip(om,co):
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for o,c in zip(om,co):
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print(o,c)
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assert np.allclose(single(o),c) and np.allclose(single(o),vectorized(o)), f'{o},{c}'
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assert np.allclose(single(o),c) and np.allclose(single(o),vectorized(o))
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@pytest.mark.parametrize('vectorized, single',[(Rotation._eu2qu,eu2qu),
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@pytest.mark.parametrize('vectorized, single',[(Rotation._eu2qu,eu2qu),
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(Rotation._eu2om,eu2om),
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(Rotation._eu2om,eu2om),
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@ -638,8 +630,7 @@ class TestRotation:
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vectorized(eu.reshape(eu.shape[0]//2,-1,3))
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vectorized(eu.reshape(eu.shape[0]//2,-1,3))
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co = vectorized(eu)
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co = vectorized(eu)
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for e,c in zip(eu,co):
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for e,c in zip(eu,co):
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print(e,c)
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assert np.allclose(single(e),c) and np.allclose(single(e),vectorized(e)), f'{e},{c}'
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assert np.allclose(single(e),c) and np.allclose(single(e),vectorized(e))
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@pytest.mark.parametrize('vectorized, single',[(Rotation._ax2qu,ax2qu),
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@pytest.mark.parametrize('vectorized, single',[(Rotation._ax2qu,ax2qu),
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(Rotation._ax2om,ax2om),
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(Rotation._ax2om,ax2om),
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@ -651,8 +642,7 @@ class TestRotation:
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vectorized(ax.reshape(ax.shape[0]//2,-1,4))
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vectorized(ax.reshape(ax.shape[0]//2,-1,4))
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co = vectorized(ax)
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co = vectorized(ax)
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for a,c in zip(ax,co):
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for a,c in zip(ax,co):
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print(a,c)
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assert np.allclose(single(a),c) and np.allclose(single(a),vectorized(a)), f'{a},{c}'
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assert np.allclose(single(a),c) and np.allclose(single(a),vectorized(a))
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@pytest.mark.parametrize('vectorized, single',[(Rotation._ro2ax,ro2ax),
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@pytest.mark.parametrize('vectorized, single',[(Rotation._ro2ax,ro2ax),
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@ -663,8 +653,7 @@ class TestRotation:
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vectorized(ro.reshape(ro.shape[0]//2,-1,4))
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vectorized(ro.reshape(ro.shape[0]//2,-1,4))
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co = vectorized(ro)
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co = vectorized(ro)
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for r,c in zip(ro,co):
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for r,c in zip(ro,co):
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print(r,c)
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assert np.allclose(single(r),c) and np.allclose(single(r),vectorized(r)), f'{r},{c}'
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assert np.allclose(single(r),c) and np.allclose(single(r),vectorized(r))
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@pytest.mark.parametrize('vectorized, single',[(Rotation._ho2ax,ho2ax),
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@pytest.mark.parametrize('vectorized, single',[(Rotation._ho2ax,ho2ax),
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(Rotation._ho2cu,ho2cu)])
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(Rotation._ho2cu,ho2cu)])
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@ -674,8 +663,7 @@ class TestRotation:
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vectorized(ho.reshape(ho.shape[0]//2,-1,3))
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vectorized(ho.reshape(ho.shape[0]//2,-1,3))
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co = vectorized(ho)
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co = vectorized(ho)
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for h,c in zip(ho,co):
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for h,c in zip(ho,co):
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print(h,c)
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assert np.allclose(single(h),c) and np.allclose(single(h),vectorized(h)), f'{h},{c}'
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assert np.allclose(single(h),c) and np.allclose(single(h),vectorized(h))
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@pytest.mark.parametrize('vectorized, single',[(Rotation._cu2ho,cu2ho)])
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@pytest.mark.parametrize('vectorized, single',[(Rotation._cu2ho,cu2ho)])
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def test_cubochoric_vectorization(self,set_of_rotations,vectorized,single):
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def test_cubochoric_vectorization(self,set_of_rotations,vectorized,single):
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@ -684,8 +672,7 @@ class TestRotation:
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vectorized(cu.reshape(cu.shape[0]//2,-1,3))
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vectorized(cu.reshape(cu.shape[0]//2,-1,3))
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co = vectorized(cu)
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co = vectorized(cu)
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for u,c in zip(cu,co):
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for u,c in zip(cu,co):
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print(u,c)
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assert np.allclose(single(u),c) and np.allclose(single(u),vectorized(u)), f'{u},{c}'
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assert np.allclose(single(u),c) and np.allclose(single(u),vectorized(u))
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@pytest.mark.parametrize('func',[Rotation.from_axis_angle])
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@pytest.mark.parametrize('func',[Rotation.from_axis_angle])
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def test_normalization_vectorization(self,func):
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def test_normalization_vectorization(self,func):
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@ -703,9 +690,8 @@ class TestRotation:
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o = Rotation.from_Eulers(rot.as_Eulers(degrees),degrees).as_quaternion()
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o = Rotation.from_Eulers(rot.as_Eulers(degrees),degrees).as_quaternion()
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ok = np.allclose(m,o,atol=atol)
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ok = np.allclose(m,o,atol=atol)
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if np.isclose(rot.as_quaternion()[0],0.0,atol=atol):
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if np.isclose(rot.as_quaternion()[0],0.0,atol=atol):
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ok = ok or np.allclose(m*-1.,o,atol=atol)
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ok |= np.allclose(m*-1.,o,atol=atol)
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print(m,o,rot.as_quaternion())
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assert ok and np.isclose(np.linalg.norm(o),1.0), f'{m},{o},{rot.as_quaternion()}'
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assert ok and np.isclose(np.linalg.norm(o),1.0)
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@pytest.mark.parametrize('P',[1,-1])
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@pytest.mark.parametrize('P',[1,-1])
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@pytest.mark.parametrize('normalize',[True,False])
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@pytest.mark.parametrize('normalize',[True,False])
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@ -717,12 +703,12 @@ class TestRotation:
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o = Rotation.from_axis_angle(rot.as_axis_angle(degrees)*c,degrees,normalize,P).as_Eulers()
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o = Rotation.from_axis_angle(rot.as_axis_angle(degrees)*c,degrees,normalize,P).as_Eulers()
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u = np.array([np.pi*2,np.pi,np.pi*2])
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u = np.array([np.pi*2,np.pi,np.pi*2])
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ok = np.allclose(m,o,atol=atol)
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ok = np.allclose(m,o,atol=atol)
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ok = ok or np.allclose(np.where(np.isclose(m,u),m-u,m),np.where(np.isclose(o,u),o-u,o),atol=atol)
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ok |= np.allclose(np.where(np.isclose(m,u),m-u,m),np.where(np.isclose(o,u),o-u,o),atol=atol)
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if np.isclose(m[1],0.0,atol=atol) or np.isclose(m[1],np.pi,atol=atol):
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if np.isclose(m[1],0.0,atol=atol) or np.isclose(m[1],np.pi,atol=atol):
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sum_phi = np.unwrap([m[0]+m[2],o[0]+o[2]])
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sum_phi = np.unwrap([m[0]+m[2],o[0]+o[2]])
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ok = ok or np.isclose(sum_phi[0],sum_phi[1],atol=atol)
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ok |= np.isclose(sum_phi[0],sum_phi[1],atol=atol)
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print(m,o,rot.as_quaternion())
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assert ok and (np.zeros(3)-1.e-9 <= o).all() \
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assert ok and (np.zeros(3)-1.e-9 <= o).all() and (o <= np.array([np.pi*2.,np.pi,np.pi*2.])+1.e-9).all()
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and (o <= np.array([np.pi*2.,np.pi,np.pi*2.])+1.e-9).all(), f'{m},{o},{rot.as_quaternion()}'
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def test_matrix(self,set_of_rotations):
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def test_matrix(self,set_of_rotations):
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for rot in set_of_rotations:
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for rot in set_of_rotations:
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@ -731,8 +717,8 @@ class TestRotation:
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ok = np.allclose(m,o,atol=atol)
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ok = np.allclose(m,o,atol=atol)
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if np.isclose(m[3],np.pi,atol=atol):
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if np.isclose(m[3],np.pi,atol=atol):
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ok = ok or np.allclose(m*np.array([-1.,-1.,-1.,1.]),o,atol=atol)
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ok = ok or np.allclose(m*np.array([-1.,-1.,-1.,1.]),o,atol=atol)
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print(m,o,rot.as_quaternion())
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assert ok and np.isclose(np.linalg.norm(o[:3]),1.0) \
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assert ok and np.isclose(np.linalg.norm(o[:3]),1.0) and o[3]<=np.pi+1.e-9
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and o[3]<=np.pi+1.e-9, f'{m},{o},{rot.as_quaternion()}'
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@pytest.mark.parametrize('P',[1,-1])
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@pytest.mark.parametrize('P',[1,-1])
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@pytest.mark.parametrize('normalize',[True,False])
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@pytest.mark.parametrize('normalize',[True,False])
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@ -742,8 +728,7 @@ class TestRotation:
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m = rot.as_matrix()
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m = rot.as_matrix()
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o = Rotation.from_Rodrigues(rot.as_Rodrigues()*c,normalize,P).as_matrix()
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o = Rotation.from_Rodrigues(rot.as_Rodrigues()*c,normalize,P).as_matrix()
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ok = np.allclose(m,o,atol=atol)
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ok = np.allclose(m,o,atol=atol)
|
||||||
print(m,o)
|
assert ok and np.isclose(np.linalg.det(o),1.0), f'{m},{o}'
|
||||||
assert ok and np.isclose(np.linalg.det(o),1.0)
|
|
||||||
|
|
||||||
@pytest.mark.parametrize('P',[1,-1])
|
@pytest.mark.parametrize('P',[1,-1])
|
||||||
def test_homochoric(self,set_of_rotations,P):
|
def test_homochoric(self,set_of_rotations,P):
|
||||||
|
@ -753,8 +738,7 @@ class TestRotation:
|
||||||
o = Rotation.from_homochoric(rot.as_homochoric()*P*-1,P).as_Rodrigues()
|
o = Rotation.from_homochoric(rot.as_homochoric()*P*-1,P).as_Rodrigues()
|
||||||
ok = np.allclose(np.clip(m,None,cutoff),np.clip(o,None,cutoff),atol=atol)
|
ok = np.allclose(np.clip(m,None,cutoff),np.clip(o,None,cutoff),atol=atol)
|
||||||
ok = ok or np.isclose(m[3],0.0,atol=atol)
|
ok = ok or np.isclose(m[3],0.0,atol=atol)
|
||||||
print(m,o,rot.as_quaternion())
|
assert ok and np.isclose(np.linalg.norm(o[:3]),1.0), f'{m},{o},{rot.as_quaternion()}'
|
||||||
assert ok and np.isclose(np.linalg.norm(o[:3]),1.0)
|
|
||||||
|
|
||||||
@pytest.mark.parametrize('P',[1,-1])
|
@pytest.mark.parametrize('P',[1,-1])
|
||||||
def test_cubochoric(self,set_of_rotations,P):
|
def test_cubochoric(self,set_of_rotations,P):
|
||||||
|
@ -762,8 +746,7 @@ class TestRotation:
|
||||||
m = rot.as_homochoric()
|
m = rot.as_homochoric()
|
||||||
o = Rotation.from_cubochoric(rot.as_cubochoric()*P*-1,P).as_homochoric()
|
o = Rotation.from_cubochoric(rot.as_cubochoric()*P*-1,P).as_homochoric()
|
||||||
ok = np.allclose(m,o,atol=atol)
|
ok = np.allclose(m,o,atol=atol)
|
||||||
print(m,o,rot.as_quaternion())
|
assert ok and np.linalg.norm(o) < (3.*np.pi/4.)**(1./3.) + 1.e-9, f'{m},{o},{rot.as_quaternion()}'
|
||||||
assert ok and np.linalg.norm(o) < (3.*np.pi/4.)**(1./3.) + 1.e-9
|
|
||||||
|
|
||||||
@pytest.mark.parametrize('P',[1,-1])
|
@pytest.mark.parametrize('P',[1,-1])
|
||||||
@pytest.mark.parametrize('accept_homomorph',[True,False])
|
@pytest.mark.parametrize('accept_homomorph',[True,False])
|
||||||
|
@ -774,9 +757,8 @@ class TestRotation:
|
||||||
o = Rotation.from_quaternion(rot.as_quaternion()*c,accept_homomorph,P).as_cubochoric()
|
o = Rotation.from_quaternion(rot.as_quaternion()*c,accept_homomorph,P).as_cubochoric()
|
||||||
ok = np.allclose(m,o,atol=atol)
|
ok = np.allclose(m,o,atol=atol)
|
||||||
if np.count_nonzero(np.isclose(np.abs(o),np.pi**(2./3.)*.5)):
|
if np.count_nonzero(np.isclose(np.abs(o),np.pi**(2./3.)*.5)):
|
||||||
ok = ok or np.allclose(m*-1.,o,atol=atol)
|
ok |= np.allclose(m*-1.,o,atol=atol)
|
||||||
print(m,o,rot.as_quaternion())
|
assert ok and o.max() < np.pi**(2./3.)*0.5+1.e-9, f'{m},{o},{rot.as_quaternion()}'
|
||||||
assert ok and o.max() < np.pi**(2./3.)*0.5+1.e-9
|
|
||||||
|
|
||||||
@pytest.mark.parametrize('reciprocal',[True,False])
|
@pytest.mark.parametrize('reciprocal',[True,False])
|
||||||
def test_basis(self,set_of_rotations,reciprocal):
|
def test_basis(self,set_of_rotations,reciprocal):
|
||||||
|
@ -858,8 +840,7 @@ class TestRotation:
|
||||||
for rot in set_of_rotations:
|
for rot in set_of_rotations:
|
||||||
v = rot.broadcast_to((5,)) @ data
|
v = rot.broadcast_to((5,)) @ data
|
||||||
for i in range(data.shape[0]):
|
for i in range(data.shape[0]):
|
||||||
print(i-data[i])
|
assert np.allclose(mul(rot,data[i]),v[i]), f'{i-data[i]}'
|
||||||
assert np.allclose(mul(rot,data[i]),v[i])
|
|
||||||
|
|
||||||
|
|
||||||
@pytest.mark.parametrize('data',[np.random.rand(3),
|
@pytest.mark.parametrize('data',[np.random.rand(3),
|
||||||
|
@ -927,33 +908,31 @@ class TestRotation:
|
||||||
@pytest.mark.parametrize('N',[1000,10000,100000])
|
@pytest.mark.parametrize('N',[1000,10000,100000])
|
||||||
def test_spherical_component(self,N,sigma):
|
def test_spherical_component(self,N,sigma):
|
||||||
c = Rotation.from_random()
|
c = Rotation.from_random()
|
||||||
o = Rotation.from_spherical_component(c,sigma,N)
|
o = Rotation.from_spherical_component(c,sigma,N,seed=N+sigma)
|
||||||
_, angles = c.misorientation(o).as_axis_angle(pair=True,degrees=True)
|
_, angles = c.misorientation(o).as_axis_angle(pair=True,degrees=True)
|
||||||
angles[::2] *= -1 # flip angle for every second to symmetrize distribution
|
angles[::2] *= -1 # flip angle for every second to symmetrize distribution
|
||||||
|
|
||||||
p = stats.normaltest(angles)[1]
|
p = stats.normaltest(angles)[1]
|
||||||
sigma_out = np.std(angles)
|
sigma_out = np.std(angles)
|
||||||
print(f'\np: {p}, sigma ratio {sigma/sigma_out}')
|
assert (.9 < sigma/sigma_out < 1.1) and p > 1, f'{sigma/sigma_out},{p}'
|
||||||
assert (.9 < sigma/sigma_out < 1.1) and p > 0.001
|
|
||||||
|
|
||||||
|
|
||||||
@pytest.mark.parametrize('sigma',[5,10,15,20])
|
@pytest.mark.parametrize('sigma',[5,10,15,20])
|
||||||
@pytest.mark.parametrize('N',[1000,10000,100000])
|
@pytest.mark.parametrize('N',[1000,10000,100000])
|
||||||
def test_from_fiber_component(self,N,sigma):
|
def test_from_fiber_component(self,N,sigma):
|
||||||
"""https://en.wikipedia.org/wiki/Full_width_at_half_maximum."""
|
"""https://en.wikipedia.org/wiki/Full_width_at_half_maximum."""
|
||||||
alpha = np.random.random(2)*np.pi
|
alpha = np.random.random()*2*np.pi,np.arccos(np.random.random())
|
||||||
beta = np.random.random(2)*np.pi
|
beta = np.random.random()*2*np.pi,np.arccos(np.random.random())
|
||||||
|
|
||||||
f_in_C = np.array([np.sin(alpha[0])*np.cos(alpha[1]), np.sin(alpha[0])*np.sin(alpha[1]), np.cos(alpha[0])])
|
f_in_C = np.array([np.sin(alpha[0])*np.cos(alpha[1]), np.sin(alpha[0])*np.sin(alpha[1]), np.cos(alpha[0])])
|
||||||
f_in_S = np.array([np.sin(beta[0] )*np.cos(beta[1] ), np.sin(beta[0] )*np.sin(beta[1] ), np.cos(beta[0] )])
|
f_in_S = np.array([np.sin(beta[0] )*np.cos(beta[1] ), np.sin(beta[0] )*np.sin(beta[1] ), np.cos(beta[0] )])
|
||||||
ax = np.append(np.cross(f_in_C,f_in_S), - np.arccos(np.dot(f_in_C,f_in_S)))
|
ax = np.append(np.cross(f_in_C,f_in_S), - np.arccos(np.dot(f_in_C,f_in_S)))
|
||||||
n = Rotation.from_axis_angle(ax if ax[3] > 0.0 else ax*-1.0 ,normalize=True) # rotation to align fiber axis in crystal and sample system
|
n = Rotation.from_axis_angle(ax if ax[3] > 0.0 else ax*-1.0 ,normalize=True) # rotation to align fiber axis in crystal and sample system
|
||||||
|
|
||||||
o = Rotation.from_fiber_component(alpha,beta,np.radians(sigma),N,False)
|
o = Rotation.from_fiber_component(alpha,beta,np.radians(sigma),N,False,seed=N+sigma)
|
||||||
angles = np.arccos(np.clip(np.dot(o@np.broadcast_to(f_in_S,(N,3)),n@f_in_S),-1,1))
|
angles = np.arccos(np.clip(np.dot(o@np.broadcast_to(f_in_S,(N,3)),n@f_in_S),-1,1))
|
||||||
dist = np.array(angles) * (np.random.randint(0,2,N)*2-1)
|
dist = np.array(angles) * (np.random.randint(0,2,N)*2-1)
|
||||||
|
|
||||||
p = stats.normaltest(dist)[1]
|
p = stats.normaltest(dist)[1]
|
||||||
sigma_out = np.degrees(np.std(dist))
|
sigma_out = np.degrees(np.std(dist))
|
||||||
print(f'\np: {p}, sigma ratio {sigma/sigma_out}')
|
assert (.9 < sigma/sigma_out < 1.1) and p > 0.001, f'{sigma/sigma_out},{p}'
|
||||||
assert (.9 < sigma/sigma_out < 1.1) and p > 0.001
|
|
||||||
|
|
Loading…
Reference in New Issue