Vehicle-Anti-Theft-Face-Rec.../venv/Lib/site-packages/scipy/sparse/linalg/tests/test_interface.py

451 lines
16 KiB
Python
Raw Normal View History

"""Test functions for the sparse.linalg.interface module
"""
from functools import partial
from itertools import product
import operator
import pytest
from pytest import raises as assert_raises, warns
from numpy.testing import assert_, assert_equal
import numpy as np
import scipy.sparse as sparse
from scipy.sparse.linalg import interface
from scipy.sparse.sputils import matrix
class TestLinearOperator(object):
def setup_method(self):
self.A = np.array([[1,2,3],
[4,5,6]])
self.B = np.array([[1,2],
[3,4],
[5,6]])
self.C = np.array([[1,2],
[3,4]])
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))
def test_matmul(self):
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]),
'rmatmat': lambda x: np.dot(self.A.T.conj(), x),
'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)
class TestAsLinearOperator(object):
def setup_method(self):
self.cases = []
def make_cases(original, dtype):
cases = []
cases.append((matrix(original, dtype=dtype), original))
cases.append((np.array(original, dtype=dtype), original))
cases.append((sparse.csr_matrix(original, dtype=dtype), original))
# Test default implementations of _adjoint and _rmatvec, which
# refer to each other.
def mv(x, dtype):
y = original.dot(x)
if len(x.shape) == 2:
y = y.reshape(-1, 1)
return y
def rmv(x, dtype):
return original.T.conj().dot(x)
class BaseMatlike(interface.LinearOperator):
args = ()
def __init__(self, dtype):
self.dtype = np.dtype(dtype)
self.shape = original.shape
def _matvec(self, x):
return mv(x, self.dtype)
class HasRmatvec(BaseMatlike):
args = ()
def _rmatvec(self,x):
return rmv(x, self.dtype)
class HasAdjoint(BaseMatlike):
args = ()
def _adjoint(self):
shape = self.shape[1], self.shape[0]
matvec = partial(rmv, dtype=self.dtype)
rmatvec = partial(mv, dtype=self.dtype)
return interface.LinearOperator(matvec=matvec,
rmatvec=rmatvec,
dtype=self.dtype,
shape=shape)
class HasRmatmat(HasRmatvec):
def _matmat(self, x):
return original.dot(x)
def _rmatmat(self, x):
return original.T.conj().dot(x)
cases.append((HasRmatvec(dtype), original))
cases.append((HasAdjoint(dtype), original))
cases.append((HasRmatmat(dtype), original))
return cases
original = np.array([[1,2,3], [4,5,6]])
self.cases += make_cases(original, np.int32)
self.cases += make_cases(original, np.float32)
self.cases += make_cases(original, np.float64)
self.cases += [(interface.aslinearoperator(M).T, A.T)
for M, A in make_cases(original.T, np.float64)]
self.cases += [(interface.aslinearoperator(M).H, A.T.conj())
for M, A in make_cases(original.T, np.float64)]
original = np.array([[1, 2j, 3j], [4j, 5j, 6]])
self.cases += make_cases(original, np.complex_)
self.cases += [(interface.aslinearoperator(M).T, A.T)
for M, A in make_cases(original.T, np.complex_)]
self.cases += [(interface.aslinearoperator(M).H, A.T.conj())
for M, A in make_cases(original.T, np.complex_)]
def test_basic(self):
for M, A_array in self.cases:
A = interface.aslinearoperator(M)
M,N = A.shape
xs = [np.array([1, 2, 3]),
np.array([[1], [2], [3]])]
ys = [np.array([1, 2]), np.array([[1], [2]])]
if A.dtype == np.complex_:
xs += [np.array([1, 2j, 3j]),
np.array([[1], [2j], [3j]])]
ys += [np.array([1, 2j]), np.array([[1], [2j]])]
x2 = np.array([[1, 4], [2, 5], [3, 6]])
for x in xs:
assert_equal(A.matvec(x), A_array.dot(x))
assert_equal(A * x, A_array.dot(x))
assert_equal(A.matmat(x2), A_array.dot(x2))
assert_equal(A * x2, A_array.dot(x2))
for y in ys:
assert_equal(A.rmatvec(y), A_array.T.conj().dot(y))
assert_equal(A.T.matvec(y), A_array.T.dot(y))
assert_equal(A.H.matvec(y), A_array.T.conj().dot(y))
for y in ys:
if y.ndim < 2:
continue
assert_equal(A.rmatmat(y), A_array.T.conj().dot(y))
assert_equal(A.T.matmat(y), A_array.T.dot(y))
assert_equal(A.H.matmat(y), A_array.T.conj().dot(y))
if hasattr(M,'dtype'):
assert_equal(A.dtype, M.dtype)
assert_(hasattr(A, 'args'))
def test_dot(self):
for M, A_array in self.cases:
A = interface.aslinearoperator(M)
M,N = A.shape
x0 = np.array([1, 2, 3])
x1 = np.array([[1], [2], [3]])
x2 = np.array([[1, 4], [2, 5], [3, 6]])
assert_equal(A.dot(x0), A_array.dot(x0))
assert_equal(A.dot(x1), A_array.dot(x1))
assert_equal(A.dot(x2), A_array.dot(x2))
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_identity():
ident = interface.IdentityOperator((3, 3))
assert_equal(ident * [1, 2, 3], [1, 2, 3])
assert_equal(ident.dot(np.arange(9).reshape(3, 3)).ravel(), np.arange(9))
assert_raises(ValueError, ident.matvec, [1, 2, 3, 4])
def test_attributes():
A = interface.aslinearoperator(np.arange(16).reshape(4, 4))
def always_four_ones(x):
x = np.asarray(x)
assert_(x.shape == (3,) or x.shape == (3, 1))
return np.ones(4)
B = interface.LinearOperator(shape=(4, 3), matvec=always_four_ones)
for op in [A, B, A * B, A.H, A + A, B + B, A**4]:
assert_(hasattr(op, "dtype"))
assert_(hasattr(op, "shape"))
assert_(hasattr(op, "_matvec"))
def matvec(x):
""" Needed for test_pickle as local functions are not pickleable """
return np.zeros(3)
def test_pickle():
import pickle
for protocol in range(pickle.HIGHEST_PROTOCOL + 1):
A = interface.LinearOperator((3, 3), matvec)
s = pickle.dumps(A, protocol=protocol)
B = pickle.loads(s)
for k in A.__dict__:
assert_equal(getattr(A, k), getattr(B, k))
def test_inheritance():
class Empty(interface.LinearOperator):
pass
with warns(RuntimeWarning, match="should implement at least"):
assert_raises(TypeError, Empty)
class Identity(interface.LinearOperator):
def __init__(self, n):
super(Identity, self).__init__(dtype=None, shape=(n, n))
def _matvec(self, x):
return x
id3 = Identity(3)
assert_equal(id3.matvec([1, 2, 3]), [1, 2, 3])
assert_raises(NotImplementedError, id3.rmatvec, [4, 5, 6])
class MatmatOnly(interface.LinearOperator):
def __init__(self, A):
super(MatmatOnly, self).__init__(A.dtype, A.shape)
self.A = A
def _matmat(self, x):
return self.A.dot(x)
mm = MatmatOnly(np.random.randn(5, 3))
assert_equal(mm.matvec(np.random.randn(3)).shape, (5,))
def test_dtypes_of_operator_sum():
# gh-6078
mat_complex = np.random.rand(2,2) + 1j * np.random.rand(2,2)
mat_real = np.random.rand(2,2)
complex_operator = interface.aslinearoperator(mat_complex)
real_operator = interface.aslinearoperator(mat_real)
sum_complex = complex_operator + complex_operator
sum_real = real_operator + real_operator
assert_equal(sum_real.dtype, np.float64)
assert_equal(sum_complex.dtype, np.complex128)
def test_no_double_init():
call_count = [0]
def matvec(v):
call_count[0] += 1
return v
# It should call matvec exactly once (in order to determine the
# operator dtype)
interface.LinearOperator((2, 2), matvec=matvec)
assert_equal(call_count[0], 1)
def test_adjoint_conjugate():
X = np.array([[1j]])
A = interface.aslinearoperator(X)
B = 1j * A
Y = 1j * X
v = np.array([1])
assert_equal(B.dot(v), Y.dot(v))
assert_equal(B.H.dot(v), Y.T.conj().dot(v))
def test_ndim():
X = np.array([[1]])
A = interface.aslinearoperator(X)
assert_equal(A.ndim, 2)
def test_transpose_noconjugate():
X = np.array([[1j]])
A = interface.aslinearoperator(X)
B = 1j * A
Y = 1j * X
v = np.array([1])
assert_equal(B.dot(v), Y.dot(v))
assert_equal(B.T.dot(v), Y.T.dot(v))