def test_matmul(self):
if not TEST_MATMUL:
pytest.skip("matmul is only tested in Python 3.5+")
D = {'shape': self.A.shape,
'matvec': lambda x: np.dot(self.A, x).reshape(self.A.shape[0]),
'rmatvec': lambda x: np.dot(self.A.T.conj(),
x).reshape(self.A.shape[1]),
'matmat': lambda x: np.dot(self.A, x)}
A = interface.LinearOperator(**D)
B = np.array([[1, 2, 3],
[4, 5, 6],
[7, 8, 9]])
b = B[0]
assert_equal(operator.matmul(A, b), A * b)
assert_equal(operator.matmul(A, B), A * B)
assert_raises(ValueError, operator.matmul, A, 2)
assert_raises(ValueError, operator.matmul, 2, A)
def test_repr():
A = interface.LinearOperator(shape=(1, 1), matvec=lambda x: 1)
repr_A = repr(A)
assert_('unspecified dtype' not in repr_A, repr_A)
def test_matvec(self):
def get_matvecs(A):
return [{
'shape':
A.shape,
'matvec':
lambda x: np.dot(A, x).reshape(A.shape[0]),
'rmatvec':
lambda x: np.dot(A.T.conj(), x).reshape(A.shape[1])
}, {
'shape': A.shape,
'matvec': lambda x: np.dot(A, x),
'rmatvec': lambda x: np.dot(A.T.conj(), x),
'rmatmat': lambda x: np.dot(A.T.conj(), x),
'matmat': lambda x: np.dot(A, x)
}]
for matvecs in get_matvecs(self.A):
A = interface.LinearOperator(**matvecs)
assert_(A.args == ())
assert_equal(A.matvec(np.array([1, 2, 3])), [14, 32])
assert_equal(A.matvec(np.array([[1], [2], [3]])), [[14], [32]])
assert_equal(A * np.array([1, 2, 3]), [14, 32])
assert_equal(A * np.array([[1], [2], [3]]), [[14], [32]])
assert_equal(A.dot(np.array([1, 2, 3])), [14, 32])
assert_equal(A.dot(np.array([[1], [2], [3]])), [[14], [32]])
assert_equal(A.matvec(matrix([[1], [2], [3]])), [[14], [32]])
assert_equal(A * matrix([[1], [2], [3]]), [[14], [32]])
assert_equal(A.dot(matrix([[1], [2], [3]])), [[14], [32]])
assert_equal((2 * A) * [1, 1, 1], [12, 30])
assert_equal((2 * A).rmatvec([1, 1]), [10, 14, 18])
assert_equal((2 * A).H.matvec([1, 1]), [10, 14, 18])
assert_equal((2 * A) * [[1], [1], [1]], [[12], [30]])
assert_equal((2 * A).matmat([[1], [1], [1]]), [[12], [30]])
assert_equal((A * 2) * [1, 1, 1], [12, 30])
assert_equal((A * 2) * [[1], [1], [1]], [[12], [30]])
assert_equal((2j * A) * [1, 1, 1], [12j, 30j])
assert_equal((A + A) * [1, 1, 1], [12, 30])
assert_equal((A + A).rmatvec([1, 1]), [10, 14, 18])
assert_equal((A + A).H.matvec([1, 1]), [10, 14, 18])
assert_equal((A + A) * [[1], [1], [1]], [[12], [30]])
assert_equal((A + A).matmat([[1], [1], [1]]), [[12], [30]])
assert_equal((-A) * [1, 1, 1], [-6, -15])
assert_equal((-A) * [[1], [1], [1]], [[-6], [-15]])
assert_equal((A - A) * [1, 1, 1], [0, 0])
assert_equal((A - A) * [[1], [1], [1]], [[0], [0]])
X = np.array([[1, 2], [3, 4]])
# A_asarray = np.array([[1, 2, 3], [4, 5, 6]])
assert_equal((2 * A).rmatmat(X), np.dot((2 * self.A).T, X))
assert_equal((A * 2).rmatmat(X), np.dot((self.A * 2).T, X))
assert_equal((2j * A).rmatmat(X), np.dot((2j * self.A).T.conj(),
X))
assert_equal((A * 2j).rmatmat(X), np.dot((self.A * 2j).T.conj(),
X))
assert_equal((A + A).rmatmat(X), np.dot((self.A + self.A).T, X))
assert_equal((A + 2j * A).rmatmat(X),
np.dot((self.A + 2j * self.A).T.conj(), X))
assert_equal((-A).rmatmat(X), np.dot((-self.A).T, X))
assert_equal((A - A).rmatmat(X), np.dot((self.A - self.A).T, X))
assert_equal((2j * A).rmatmat(2j * X),
np.dot((2j * self.A).T.conj(), 2j * X))
z = A + A
assert_(len(z.args) == 2 and z.args[0] is A and z.args[1] is A)
z = 2 * A
assert_(len(z.args) == 2 and z.args[0] is A and z.args[1] == 2)
assert_(isinstance(A.matvec([1, 2, 3]), np.ndarray))
assert_(isinstance(A.matvec(np.array([[1], [2], [3]])),
np.ndarray))
assert_(isinstance(A * np.array([1, 2, 3]), np.ndarray))
assert_(isinstance(A * np.array([[1], [2], [3]]), np.ndarray))
assert_(isinstance(A.dot(np.array([1, 2, 3])), np.ndarray))
assert_(isinstance(A.dot(np.array([[1], [2], [3]])), np.ndarray))
assert_(isinstance(A.matvec(matrix([[1], [2], [3]])), np.ndarray))
assert_(isinstance(A * matrix([[1], [2], [3]]), np.ndarray))
assert_(isinstance(A.dot(matrix([[1], [2], [3]])), np.ndarray))
assert_(isinstance(2 * A, interface._ScaledLinearOperator))
assert_(isinstance(2j * A, interface._ScaledLinearOperator))
assert_(isinstance(A + A, interface._SumLinearOperator))
assert_(isinstance(-A, interface._ScaledLinearOperator))
assert_(isinstance(A - A, interface._SumLinearOperator))
assert_((2j * A).dtype == np.complex_)
assert_raises(ValueError, A.matvec, np.array([1, 2]))
assert_raises(ValueError, A.matvec, np.array([1, 2, 3, 4]))
assert_raises(ValueError, A.matvec, np.array([[1], [2]]))
assert_raises(ValueError, A.matvec, np.array([[1], [2], [3], [4]]))
assert_raises(ValueError, lambda: A * A)
assert_raises(ValueError, lambda: A**2)
for matvecsA, matvecsB in product(get_matvecs(self.A),
get_matvecs(self.B)):
A = interface.LinearOperator(**matvecsA)
B = interface.LinearOperator(**matvecsB)
# AtimesB = np.array([[22, 28], [49, 64]])
AtimesB = self.A.dot(self.B)
X = np.array([[1, 2], [3, 4]])
assert_equal((A * B).rmatmat(X), np.dot((AtimesB).T, X))
assert_equal((2j * A * B).rmatmat(X),
np.dot((2j * AtimesB).T.conj(), X))
assert_equal((A * B) * [1, 1], [50, 113])
assert_equal((A * B) * [[1], [1]], [[50], [113]])
assert_equal((A * B).matmat([[1], [1]]), [[50], [113]])
assert_equal((A * B).rmatvec([1, 1]), [71, 92])
assert_equal((A * B).H.matvec([1, 1]), [71, 92])
assert_(isinstance(A * B, interface._ProductLinearOperator))
assert_raises(ValueError, lambda: A + B)
assert_raises(ValueError, lambda: A**2)
z = A * B
assert_(len(z.args) == 2 and z.args[0] is A and z.args[1] is B)
for matvecsC in get_matvecs(self.C):
C = interface.LinearOperator(**matvecsC)
X = np.array([[1, 2], [3, 4]])
assert_equal(C.rmatmat(X), np.dot((self.C).T, X))
assert_equal((C**2).rmatmat(X),
np.dot((np.dot(self.C, self.C)).T, X))
assert_equal((C**2) * [1, 1], [17, 37])
assert_equal((C**2).rmatvec([1, 1]), [22, 32])
assert_equal((C**2).H.matvec([1, 1]), [22, 32])
assert_equal((C**2).matmat([[1], [1]]), [[17], [37]])
assert_(isinstance(C**2, interface._PowerLinearOperator))
