class TestSingleStiefelManifold(unittest.TestCase):
def setUp(self):
self.m = m = 20
self.n = n = 2
self.k = k = 1
self.man = Stiefel(m, n, k=k)
self.proj = lambda x, u: u - npa.dot(x, npa.dot(x.T, u) +
npa.dot(u.T, x)) / 2
def test_dim(self):
assert self.man.dim == 0.5 * self.n * (2 * self.m - self.n - 1)
# def test_typicaldist(self):
# def test_dist(self):
def test_inner(self):
X = la.qr(rnd.randn(self.m, self.n))[0]
A, B = rnd.randn(2, self.m, self.n)
np_testing.assert_allclose(np.sum(A * B), self.man.inner(X, A, B))
def test_proj(self):
# Construct a random point X on the manifold.
X = rnd.randn(self.m, self.n)
X = la.qr(X)[0]
# Construct a vector H in the ambient space.
H = rnd.randn(self.m, self.n)
# Compare the projections.
Hproj = H - X.dot(X.T.dot(H) + H.T.dot(X)) / 2
np_testing.assert_allclose(Hproj, self.man.proj(X, H))
def test_rand(self):
# Just make sure that things generated are on the manifold and that
# if you generate two they are not equal.
X = self.man.rand()
np_testing.assert_allclose(X.T.dot(X), np.eye(self.n), atol=1e-10)
Y = self.man.rand()
assert np.linalg.norm(X - Y) > 1e-6
def test_randvec(self):
# Make sure things generated are in tangent space and if you generate
# two then they are not equal.
X = self.man.rand()
U = self.man.randvec(X)
np_testing.assert_allclose(multisym(X.T.dot(U)),
np.zeros((self.n, self.n)), atol=1e-10)
V = self.man.randvec(X)
assert la.norm(U - V) > 1e-6
def test_retr(self):
# Test that the result is on the manifold and that for small
# tangent vectors it has little effect.
x = self.man.rand()
u = self.man.randvec(x)
xretru = self.man.retr(x, u)
np_testing.assert_allclose(xretru.T.dot(xretru), np.eye(self.n,
self.n),
atol=1e-10)
u = u * 1e-6
xretru = self.man.retr(x, u)
np_testing.assert_allclose(xretru, x + u)
def test_ehess2rhess(self):
# Test this function at some randomly generated point.
x = self.man.rand()
u = self.man.randvec(x)
egrad = rnd.randn(self.m, self.n)
ehess = rnd.randn(self.m, self.n)
np_testing.assert_allclose(testing.ehess2rhess(self.proj)(x, egrad,
ehess, u),
self.man.ehess2rhess(x, egrad, ehess, u))
# def test_egrad2rgrad(self):
def test_norm(self):
x = self.man.rand()
u = self.man.randvec(x)
np_testing.assert_almost_equal(self.man.norm(x, u), la.norm(u))
# def test_transp(self):
def test_exp(self):
# Check that exp lies on the manifold and that exp of a small vector u
# is close to x + u.
s = self.man
x = s.rand()
u = s.randvec(x)
xexpu = s.exp(x, u)
np_testing.assert_allclose(xexpu.T.dot(xexpu), np.eye(self.n,
self.n),
atol=1e-10)
u = u * 1e-6
xexpu = s.exp(x, u)
np_testing.assert_allclose(xexpu, x + u)
class TestSingleStiefelManifold(unittest.TestCase):
def setUp(self):
self.m = m = 20
self.n = n = 2
self.k = k = 1
self.man = Stiefel(m, n, k=k)
self.proj = lambda x, u: u - npa.dot(x, npa.dot(x.T, u) +
npa.dot(u.T, x)) / 2
def test_dim(self):
assert self.man.dim == 0.5 * self.n * (2 * self.m - self.n - 1)
# def test_typicaldist(self):
# def test_dist(self):
def test_inner(self):
X = la.qr(rnd.randn(self.m, self.n))[0]
A, B = rnd.randn(2, self.m, self.n)
np_testing.assert_allclose(np.sum(A * B), self.man.inner(X, A, B))
def test_proj(self):
# Construct a random point X on the manifold.
X = rnd.randn(self.m, self.n)
X = la.qr(X)[0]
# Construct a vector H in the ambient space.
H = rnd.randn(self.m, self.n)
# Compare the projections.
Hproj = H - X.dot(X.T.dot(H) + H.T.dot(X)) / 2
np_testing.assert_allclose(Hproj, self.man.proj(X, H))
def test_rand(self):
# Just make sure that things generated are on the manifold and that
# if you generate two they are not equal.
X = self.man.rand()
np_testing.assert_allclose(X.T.dot(X), np.eye(self.n), atol=1e-10)
Y = self.man.rand()
assert np.linalg.norm(X - Y) > 1e-6
def test_randvec(self):
# Make sure things generated are in tangent space and if you generate
# two then they are not equal.
X = self.man.rand()
U = self.man.randvec(X)
np_testing.assert_allclose(multisym(X.T.dot(U)),
np.zeros((self.n, self.n)), atol=1e-10)
V = self.man.randvec(X)
assert la.norm(U - V) > 1e-6
def test_retr(self):
# Test that the result is on the manifold and that for small
# tangent vectors it has little effect.
x = self.man.rand()
u = self.man.randvec(x)
xretru = self.man.retr(x, u)
np_testing.assert_allclose(xretru.T.dot(xretru), np.eye(self.n,
self.n),
atol=1e-10)
u = u * 1e-6
xretru = self.man.retr(x, u)
np_testing.assert_allclose(xretru, x + u)
def test_ehess2rhess(self):
# Test this function at some randomly generated point.
x = self.man.rand()
u = self.man.randvec(x)
egrad = rnd.randn(self.m, self.n)
ehess = rnd.randn(self.m, self.n)
np_testing.assert_allclose(testing.ehess2rhess(self.proj)(x, egrad,
ehess, u),
self.man.ehess2rhess(x, egrad, ehess, u))
# def test_egrad2rgrad(self):
def test_norm(self):
x = self.man.rand()
u = self.man.randvec(x)
np_testing.assert_almost_equal(self.man.norm(x, u), la.norm(u))
# def test_transp(self):
def test_exp(self):
# Check that exp lies on the manifold and that exp of a small vector u
# is close to x + u.
s = self.man
x = s.rand()
u = s.randvec(x)
xexpu = s.exp(x, u)
np_testing.assert_allclose(xexpu.T.dot(xexpu), np.eye(self.n,
self.n),
atol=1e-10)
u = u * 1e-6
xexpu = s.exp(x, u)
np_testing.assert_allclose(xexpu, x + u)
class TestMultiStiefelManifold(unittest.TestCase):
def setUp(self):
self.m = m = 10
self.n = n = 3
self.k = k = 3
self.man = Stiefel(m, n, k=k)
def test_dim(self):
assert self.man.dim == 0.5 * self.k * self.n * (2 * self.m - self.n -
1)
def test_typicaldist(self):
np_testing.assert_almost_equal(self.man.typicaldist,
np.sqrt(self.n * self.k))
# def test_dist(self):
def test_inner(self):
X = self.man.rand()
A = self.man.randvec(X)
B = self.man.randvec(X)
np_testing.assert_allclose(np.sum(A * B), self.man.inner(X, A, B))
def test_proj(self):
# Construct a random point X on the manifold.
X = self.man.rand()
# Construct a vector H in the ambient space.
H = rnd.randn(self.k, self.m, self.n)
# Compare the projections.
Hproj = H - multiprod(X, multiprod(multitransp(X), H) +
multiprod(multitransp(H), X)) / 2
np_testing.assert_allclose(Hproj, self.man.proj(X, H))
def test_rand(self):
# Just make sure that things generated are on the manifold and that
# if you generate two they are not equal.
X = self.man.rand()
np_testing.assert_allclose(multiprod(multitransp(X), X),
multieye(self.k, self.n), atol=1e-10)
Y = self.man.rand()
assert np.linalg.norm(X - Y) > 1e-6
def test_randvec(self):
# Make sure things generated are in tangent space and if you generate
# two then they are not equal.
X = self.man.rand()
U = self.man.randvec(X)
np_testing.assert_allclose(multisym(multiprod(multitransp(X), U)),
np.zeros((self.k, self.n, self.n)),
atol=1e-10)
V = self.man.randvec(X)
assert la.norm(U - V) > 1e-6
def test_retr(self):
# Test that the result is on the manifold and that for small
# tangent vectors it has little effect.
x = self.man.rand()
u = self.man.randvec(x)
xretru = self.man.retr(x, u)
np_testing.assert_allclose(multiprod(multitransp(xretru), xretru),
multieye(self.k, self.n),
atol=1e-10)
u = u * 1e-6
xretru = self.man.retr(x, u)
np_testing.assert_allclose(xretru, x + u)
# def test_egrad2rgrad(self):
def test_norm(self):
x = self.man.rand()
u = self.man.randvec(x)
np_testing.assert_almost_equal(self.man.norm(x, u), la.norm(u))
# def test_transp(self):
def test_exp(self):
# Check that exp lies on the manifold and that exp of a small vector u
# is close to x + u.
s = self.man
x = s.rand()
u = s.randvec(x)
xexpu = s.exp(x, u)
np_testing.assert_allclose(multiprod(multitransp(xexpu), xexpu),
multieye(self.k, self.n), atol=1e-10)
u = u * 1e-6
xexpu = s.exp(x, u)
np_testing.assert_allclose(xexpu, x + u)
class TestMultiStiefelManifold(unittest.TestCase):
def setUp(self):
self.m = m = 10
self.n = n = 3
self.k = k = 3
self.man = Stiefel(m, n, k=k)
def test_dim(self):
assert self.man.dim == 0.5 * self.k * self.n * (2 * self.m - self.n -
1)
def test_typicaldist(self):
np_testing.assert_almost_equal(self.man.typicaldist,
np.sqrt(self.n * self.k))
# def test_dist(self):
def test_inner(self):
X = self.man.rand()
A = self.man.randvec(X)
B = self.man.randvec(X)
np_testing.assert_allclose(np.sum(A * B), self.man.inner(X, A, B))
def test_proj(self):
# Construct a random point X on the manifold.
X = self.man.rand()
# Construct a vector H in the ambient space.
H = rnd.randn(self.k, self.m, self.n)
# Compare the projections.
Hproj = H - multiprod(X, multiprod(multitransp(X), H) +
multiprod(multitransp(H), X)) / 2
np_testing.assert_allclose(Hproj, self.man.proj(X, H))
def test_rand(self):
# Just make sure that things generated are on the manifold and that
# if you generate two they are not equal.
X = self.man.rand()
np_testing.assert_allclose(multiprod(multitransp(X), X),
multieye(self.k, self.n), atol=1e-10)
Y = self.man.rand()
assert np.linalg.norm(X - Y) > 1e-6
def test_randvec(self):
# Make sure things generated are in tangent space and if you generate
# two then they are not equal.
X = self.man.rand()
U = self.man.randvec(X)
np_testing.assert_allclose(multisym(multiprod(multitransp(X), U)),
np.zeros((self.k, self.n, self.n)),
atol=1e-10)
V = self.man.randvec(X)
assert la.norm(U - V) > 1e-6
def test_retr(self):
# Test that the result is on the manifold and that for small
# tangent vectors it has little effect.
x = self.man.rand()
u = self.man.randvec(x)
xretru = self.man.retr(x, u)
np_testing.assert_allclose(multiprod(multitransp(xretru), xretru),
multieye(self.k, self.n),
atol=1e-10)
u = u * 1e-6
xretru = self.man.retr(x, u)
np_testing.assert_allclose(xretru, x + u)
# def test_egrad2rgrad(self):
def test_norm(self):
x = self.man.rand()
u = self.man.randvec(x)
np_testing.assert_almost_equal(self.man.norm(x, u), la.norm(u))
# def test_transp(self):
def test_exp(self):
# Check that exp lies on the manifold and that exp of a small vector u
# is close to x + u.
s = self.man
x = s.rand()
u = s.randvec(x)
xexpu = s.exp(x, u)
np_testing.assert_allclose(multiprod(multitransp(xexpu), xexpu),
multieye(self.k, self.n), atol=1e-10)
u = u * 1e-6
xexpu = s.exp(x, u)
np_testing.assert_allclose(xexpu, x + u)