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import pytest | |
import sys | |
from mpmath import * | |
def test_matrix_basic(): | |
A1 = matrix(3) | |
for i in range(3): | |
A1[i,i] = 1 | |
assert A1 == eye(3) | |
assert A1 == matrix(A1) | |
A2 = matrix(3, 2) | |
assert not A2._matrix__data | |
A3 = matrix([[1, 2, 3], [4, 5, 6], [7, 8, 9]]) | |
assert list(A3) == list(range(1, 10)) | |
A3[1,1] = 0 | |
assert not (1, 1) in A3._matrix__data | |
A4 = matrix([[1, 2, 3], [4, 5, 6]]) | |
A5 = matrix([[6, -1], [3, 2], [0, -3]]) | |
assert A4 * A5 == matrix([[12, -6], [39, -12]]) | |
assert A1 * A3 == A3 * A1 == A3 | |
pytest.raises(ValueError, lambda: A2*A2) | |
l = [[10, 20, 30], [40, 0, 60], [70, 80, 90]] | |
A6 = matrix(l) | |
assert A6.tolist() == l | |
assert A6 == eval(repr(A6)) | |
A6 = fp.matrix(A6) | |
assert A6 == eval(repr(A6)) | |
assert A6*1j == eval(repr(A6*1j)) | |
assert A3 * 10 == 10 * A3 == A6 | |
assert A2.rows == 3 | |
assert A2.cols == 2 | |
A3.rows = 2 | |
A3.cols = 2 | |
assert len(A3._matrix__data) == 3 | |
assert A4 + A4 == 2*A4 | |
pytest.raises(ValueError, lambda: A4 + A2) | |
assert sum(A1 - A1) == 0 | |
A7 = matrix([[1, 2], [3, 4], [5, 6], [7, 8]]) | |
x = matrix([10, -10]) | |
assert A7*x == matrix([-10, -10, -10, -10]) | |
A8 = ones(5) | |
assert sum((A8 + 1) - (2 - zeros(5))) == 0 | |
assert (1 + ones(4)) / 2 - 1 == zeros(4) | |
assert eye(3)**10 == eye(3) | |
pytest.raises(ValueError, lambda: A7**2) | |
A9 = randmatrix(3) | |
A10 = matrix(A9) | |
A9[0,0] = -100 | |
assert A9 != A10 | |
assert nstr(A9) | |
def test_matmul(): | |
""" | |
Test the PEP465 "@" matrix multiplication syntax. | |
To avoid syntax errors when importing this file in Python 3.5 and below, we have to use exec() - sorry for that. | |
""" | |
# TODO remove exec() wrapper as soon as we drop support for Python <= 3.5 | |
if sys.hexversion < 0x30500f0: | |
# we are on Python < 3.5 | |
pytest.skip("'@' (__matmul__) is only supported in Python 3.5 or newer") | |
A4 = matrix([[1, 2, 3], [4, 5, 6]]) | |
A5 = matrix([[6, -1], [3, 2], [0, -3]]) | |
exec("assert A4 @ A5 == A4 * A5") | |
def test_matrix_slices(): | |
A = matrix([ [1, 2, 3], | |
[4, 5 ,6], | |
[7, 8 ,9]]) | |
V = matrix([1,2,3,4,5]) | |
# Get slice | |
assert A[:,:] == A | |
assert A[:,1] == matrix([[2],[5],[8]]) | |
assert A[2,:] == matrix([[7, 8 ,9]]) | |
assert A[1:3,1:3] == matrix([[5,6],[8,9]]) | |
assert V[2:4] == matrix([3,4]) | |
pytest.raises(IndexError, lambda: A[:,1:6]) | |
# Assign slice with matrix | |
A1 = matrix(3) | |
A1[:,:] = A | |
assert A1[:,:] == matrix([[1, 2, 3], | |
[4, 5 ,6], | |
[7, 8 ,9]]) | |
A1[0,:] = matrix([[10, 11, 12]]) | |
assert A1 == matrix([ [10, 11, 12], | |
[4, 5 ,6], | |
[7, 8 ,9]]) | |
A1[:,2] = matrix([[13], [14], [15]]) | |
assert A1 == matrix([ [10, 11, 13], | |
[4, 5 ,14], | |
[7, 8 ,15]]) | |
A1[:2,:2] = matrix([[16, 17], [18 , 19]]) | |
assert A1 == matrix([ [16, 17, 13], | |
[18, 19 ,14], | |
[7, 8 ,15]]) | |
V[1:3] = 10 | |
assert V == matrix([1,10,10,4,5]) | |
with pytest.raises(ValueError): | |
A1[2,:] = A[:,1] | |
with pytest.raises(IndexError): | |
A1[2,1:20] = A[:,:] | |
# Assign slice with scalar | |
A1[:,2] = 10 | |
assert A1 == matrix([ [16, 17, 10], | |
[18, 19 ,10], | |
[7, 8 ,10]]) | |
A1[:,:] = 40 | |
for x in A1: | |
assert x == 40 | |
def test_matrix_power(): | |
A = matrix([[1, 2], [3, 4]]) | |
assert A**2 == A*A | |
assert A**3 == A*A*A | |
assert A**-1 == inverse(A) | |
assert A**-2 == inverse(A*A) | |
def test_matrix_transform(): | |
A = matrix([[1, 2], [3, 4], [5, 6]]) | |
assert A.T == A.transpose() == matrix([[1, 3, 5], [2, 4, 6]]) | |
swap_row(A, 1, 2) | |
assert A == matrix([[1, 2], [5, 6], [3, 4]]) | |
l = [1, 2] | |
swap_row(l, 0, 1) | |
assert l == [2, 1] | |
assert extend(eye(3), [1,2,3]) == matrix([[1,0,0,1],[0,1,0,2],[0,0,1,3]]) | |
def test_matrix_conjugate(): | |
A = matrix([[1 + j, 0], [2, j]]) | |
assert A.conjugate() == matrix([[mpc(1, -1), 0], [2, mpc(0, -1)]]) | |
assert A.transpose_conj() == A.H == matrix([[mpc(1, -1), 2], | |
[0, mpc(0, -1)]]) | |
def test_matrix_creation(): | |
assert diag([1, 2, 3]) == matrix([[1, 0, 0], [0, 2, 0], [0, 0, 3]]) | |
A1 = ones(2, 3) | |
assert A1.rows == 2 and A1.cols == 3 | |
for a in A1: | |
assert a == 1 | |
A2 = zeros(3, 2) | |
assert A2.rows == 3 and A2.cols == 2 | |
for a in A2: | |
assert a == 0 | |
assert randmatrix(10) != randmatrix(10) | |
one = mpf(1) | |
assert hilbert(3) == matrix([[one, one/2, one/3], | |
[one/2, one/3, one/4], | |
[one/3, one/4, one/5]]) | |
def test_norms(): | |
# matrix norms | |
A = matrix([[1, -2], [-3, -1], [2, 1]]) | |
assert mnorm(A,1) == 6 | |
assert mnorm(A,inf) == 4 | |
assert mnorm(A,'F') == sqrt(20) | |
# vector norms | |
assert norm(-3) == 3 | |
x = [1, -2, 7, -12] | |
assert norm(x, 1) == 22 | |
assert round(norm(x, 2), 10) == 14.0712472795 | |
assert round(norm(x, 10), 10) == 12.0054633727 | |
assert norm(x, inf) == 12 | |
def test_vector(): | |
x = matrix([0, 1, 2, 3, 4]) | |
assert x == matrix([[0], [1], [2], [3], [4]]) | |
assert x[3] == 3 | |
assert len(x._matrix__data) == 4 | |
assert list(x) == list(range(5)) | |
x[0] = -10 | |
x[4] = 0 | |
assert x[0] == -10 | |
assert len(x) == len(x.T) == 5 | |
assert x.T*x == matrix([[114]]) | |
def test_matrix_copy(): | |
A = ones(6) | |
B = A.copy() | |
C = +A | |
assert A == B | |
assert A == C | |
B[0,0] = 0 | |
assert A != B | |
C[0,0] = 42 | |
assert A != C | |
def test_matrix_numpy(): | |
try: | |
import numpy | |
except ImportError: | |
return | |
l = [[1, 2], [3, 4], [5, 6]] | |
a = numpy.array(l) | |
assert matrix(l) == matrix(a) | |
def test_interval_matrix_scalar_mult(): | |
"""Multiplication of iv.matrix and any scalar type""" | |
a = mpi(-1, 1) | |
b = a + a * 2j | |
c = mpf(42) | |
d = c + c * 2j | |
e = 1.234 | |
f = fp.convert(e) | |
g = e + e * 3j | |
h = fp.convert(g) | |
M = iv.ones(1) | |
for x in [a, b, c, d, e, f, g, h]: | |
assert x * M == iv.matrix([x]) | |
assert M * x == iv.matrix([x]) | |
def test_interval_matrix_matrix_mult(): | |
"""Multiplication of iv.matrix and other matrix types""" | |
A = ones(1) | |
B = fp.ones(1) | |
M = iv.ones(1) | |
for X in [A, B, M]: | |
assert X * M == iv.matrix(X) | |
assert X * M == X | |
assert M * X == iv.matrix(X) | |
assert M * X == X | |
def test_matrix_conversion_to_iv(): | |
# Test that matrices with foreign datatypes are properly converted | |
for other_type_eye in [eye(3), fp.eye(3), iv.eye(3)]: | |
A = iv.matrix(other_type_eye) | |
B = iv.eye(3) | |
assert type(A[0,0]) == type(B[0,0]) | |
assert A.tolist() == B.tolist() | |
def test_interval_matrix_mult_bug(): | |
# regression test for interval matrix multiplication: | |
# result must be nonzero-width and contain the exact result | |
x = convert('1.00000000000001') # note: this is implicitly rounded to some near mpf float value | |
A = matrix([[x]]) | |
B = iv.matrix(A) | |
C = iv.matrix([[x]]) | |
assert B == C | |
B = B * B | |
C = C * C | |
assert B == C | |
assert B[0, 0].delta > 1e-16 | |
assert B[0, 0].delta < 3e-16 | |
assert C[0, 0].delta > 1e-16 | |
assert C[0, 0].delta < 3e-16 | |
assert mp.mpf('1.00000000000001998401444325291756783368705994138804689654') in B[0, 0] | |
assert mp.mpf('1.00000000000001998401444325291756783368705994138804689654') in C[0, 0] | |
# the following caused an error before the bug was fixed | |
assert iv.matrix(mp.eye(2)) * (iv.ones(2) + mpi(1, 2)) == iv.matrix([[mpi(2, 3), mpi(2, 3)], [mpi(2, 3), mpi(2, 3)]]) | |