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	# TODO: don't use round

	from __future__ import division

	import pytest
	from mpmath import *
	xrange = libmp.backend.xrange

	# XXX: these shouldn't be visible(?)
	LU_decomp = mp.LU_decomp
	L_solve = mp.L_solve
	U_solve = mp.U_solve
	householder = mp.householder
	improve_solution = mp.improve_solution

	A1 = matrix([[3, 1, 6],
	[2, 1, 3],
	[1, 1, 1]])
	b1 = [2, 7, 4]

	A2 = matrix([[ 2, -1, -1, 2],
	[ 6, -2, 3, -1],
	[-4, 2, 3, -2],
	[ 2, 0, 4, -3]])
	b2 = [3, -3, -2, -1]

	A3 = matrix([[ 1, 0, -1, -1, 0],
	[ 0, 1, 1, 0, -1],
	[ 4, -5, 2, 0, 0],
	[ 0, 0, -2, 9,-12],
	[ 0, 5, 0, 0, 12]])
	b3 = [0, 0, 0, 0, 50]

	A4 = matrix([[10.235, -4.56, 0., -0.035, 5.67],
	[-2.463, 1.27, 3.97, -8.63, 1.08],
	[-6.58, 0.86, -0.257, 9.32, -43.6 ],
	[ 9.83, 7.39, -17.25, 0.036, 24.86],
	[-9.31, 34.9, 78.56, 1.07, 65.8 ]])
	b4 = [8.95, 20.54, 7.42, 5.60, 58.43]

	A5 = matrix([[ 1, 2, -4],
	[-2, -3, 5],
	[ 3, 5, -8]])

	A6 = matrix([[ 1.377360, 2.481400, 5.359190],
	[ 2.679280, -1.229560, 25.560210],
	[-1.225280+1.e6, 9.910180, -35.049900-1.e6]])
	b6 = [23.500000, -15.760000, 2.340000]

	A7 = matrix([[1, -0.5],
	[2, 1],
	[-2, 6]])
	b7 = [3, 2, -4]

	A8 = matrix([[1, 2, 3],
	[-1, 0, 1],
	[-1, -2, -1],
	[1, 0, -1]])
	b8 = [1, 2, 3, 4]

	A9 = matrix([[ 4, 2, -2],
	[ 2, 5, -4],
	[-2, -4, 5.5]])
	b9 = [10, 16, -15.5]

	A10 = matrix([[1.0 + 1.0j, 2.0, 2.0],
	[4.0, 5.0, 6.0],
	[7.0, 8.0, 9.0]])
	b10 = [1.0, 1.0 + 1.0j, 1.0]


	def test_LU_decomp():
	A = A3.copy()
	b = b3
	A, p = LU_decomp(A)
	y = L_solve(A, b, p)
	x = U_solve(A, y)
	assert p == [2, 1, 2, 3]
	assert [round(i, 14) for i in x] == [3.78953107960742, 2.9989094874591098,
	-0.081788440567070006, 3.8713195201744801, 2.9171210468920399]
	A = A4.copy()
	b = b4
	A, p = LU_decomp(A)
	y = L_solve(A, b, p)
	x = U_solve(A, y)
	assert p == [0, 3, 4, 3]
	assert [round(i, 14) for i in x] == [2.6383625899619201, 2.6643834462368399,
	0.79208015947958998, -2.5088376454101899, -1.0567657691375001]
	A = randmatrix(3)
	bak = A.copy()
	LU_decomp(A, overwrite=1)
	assert A != bak

	def test_inverse():
	for A in [A1, A2, A5]:
	inv = inverse(A)
	assert mnorm(A*inv - eye(A.rows), 1) < 1.e-14

	def test_householder():
	mp.dps = 15
	A, b = A8, b8
	H, p, x, r = householder(extend(A, b))
	assert H == matrix(
	[[mpf('3.0'), mpf('-2.0'), mpf('-1.0'), 0],
	[-1.0,mpf('3.333333333333333'),mpf('-2.9999999999999991'),mpf('2.0')],
	[-1.0, mpf('-0.66666666666666674'),mpf('2.8142135623730948'),
	mpf('-2.8284271247461898')],
	[1.0, mpf('-1.3333333333333333'),mpf('-0.20000000000000018'),
	mpf('4.2426406871192857')]])
	assert p == [-2, -2, mpf('-1.4142135623730949')]
	assert round(norm(r, 2), 10) == 4.2426406870999998

	y = [102.102, 58.344, 36.463, 24.310, 17.017, 12.376, 9.282, 7.140, 5.610,
	4.488, 3.6465, 3.003]

	def coeff(n):
	# similiar to Hilbert matrix
	A = []
	for i in range(1, 13):
	A.append([1. / (i + j - 1) for j in range(1, n + 1)])
	return matrix(A)

	residuals = []
	refres = []
	for n in range(2, 7):
	A = coeff(n)
	H, p, x, r = householder(extend(A, y))
	x = matrix(x)
	y = matrix(y)
	residuals.append(norm(r, 2))
	refres.append(norm(residual(A, x, y), 2))
	assert [round(res, 10) for res in residuals] == [15.1733888877,
	0.82378073210000002, 0.302645887, 0.0260109244,
	0.00058653999999999998]
	assert norm(matrix(residuals) - matrix(refres), inf) < 1.e-13

	def hilbert_cmplx(n):
	# Complexified Hilbert matrix
	A = hilbert(2*n,n)
	v = randmatrix(2*n, 2, min=-1, max=1)
	v = v.apply(lambda x: exp(1Jpi()x))
	A = diag(v[:,0])Adiag(v[:n,1])
	return A

	residuals_cmplx = []
	refres_cmplx = []
	for n in range(2, 10):
	A = hilbert_cmplx(n)
	H, p, x, r = householder(A.copy())
	residuals_cmplx.append(norm(r, 2))
	refres_cmplx.append(norm(residual(A[:,:n-1], x, A[:,n-1]), 2))
	assert norm(matrix(residuals_cmplx) - matrix(refres_cmplx), inf) < 1.e-13

	def test_factorization():
	A = randmatrix(5)
	P, L, U = lu(A)
	assert mnorm(PA - LU, 1) < 1.e-15

	def test_solve():
	assert norm(residual(A6, lu_solve(A6, b6), b6), inf) < 1.e-10
	assert norm(residual(A7, lu_solve(A7, b7), b7), inf) < 1.5
	assert norm(residual(A8, lu_solve(A8, b8), b8), inf) <= 3 + 1.e-10
	assert norm(residual(A6, qr_solve(A6, b6)[0], b6), inf) < 1.e-10
	assert norm(residual(A7, qr_solve(A7, b7)[0], b7), inf) < 1.5
	assert norm(residual(A8, qr_solve(A8, b8)[0], b8), 2) <= 4.3
	assert norm(residual(A10, lu_solve(A10, b10), b10), 2) < 1.e-10
	assert norm(residual(A10, qr_solve(A10, b10)[0], b10), 2) < 1.e-10

	def test_solve_overdet_complex():
	A = matrix([[1, 2j], [3, 4j], [5, 6]])
	b = matrix([1 + j, 2, -j])
	assert norm(residual(A, lu_solve(A, b), b)) < 1.0208

	def test_singular():
	mp.dps = 15
	A = [[5.6, 1.2], [7./15, .1]]
	B = repr(zeros(2))
	b = [1, 2]
	for i in ['lu_solve(%s, %s)' % (A, b), 'lu_solve(%s, %s)' % (B, b),
	'qr_solve(%s, %s)' % (A, b), 'qr_solve(%s, %s)' % (B, b)]:
	pytest.raises((ZeroDivisionError, ValueError), lambda: eval(i))

	def test_cholesky():
	assert fp.cholesky(fp.matrix(A9)) == fp.matrix([[2, 0, 0], [1, 2, 0], [-1, -3/2, 3/2]])
	x = fp.cholesky_solve(A9, b9)
	assert fp.norm(fp.residual(A9, x, b9), fp.inf) == 0

	def test_det():
	assert det(A1) == 1
	assert round(det(A2), 14) == 8
	assert round(det(A3)) == 1834
	assert round(det(A4)) == 4443376
	assert det(A5) == 1
	assert round(det(A6)) == 78356463
	assert det(zeros(3)) == 0

	def test_cond():
	mp.dps = 15
	A = matrix([[1.2969, 0.8648], [0.2161, 0.1441]])
	assert cond(A, lambda x: mnorm(x,1)) == mpf('327065209.73817754')
	assert cond(A, lambda x: mnorm(x,inf)) == mpf('327065209.73817754')
	assert cond(A, lambda x: mnorm(x,'F')) == mpf('249729266.80008656')

	@extradps(50)
	def test_precision():
	A = randmatrix(10, 10)
	assert mnorm(inverse(inverse(A)) - A, 1) < 1.e-45

	def test_interval_matrix():
	mp.dps = 15
	iv.dps = 15
	a = iv.matrix([['0.1','0.3','1.0'],['7.1','5.5','4.8'],['3.2','4.4','5.6']])
	b = iv.matrix(['4','0.6','0.5'])
	c = iv.lu_solve(a, b)
	assert c[0].delta < 1e-13
	assert c[1].delta < 1e-13
	assert c[2].delta < 1e-13
	assert 5.25823271130625686059275 in c[0]
	assert -13.155049396267837541163 in c[1]
	assert 7.42069154774972557628979 in c[2]

	def test_LU_cache():
	A = randmatrix(3)
	LU = LU_decomp(A)
	assert A._LU == LU_decomp(A)
	A[0,0] = -1000
	assert A._LU is None

	def test_improve_solution():
	A = randmatrix(5, min=1e-20, max=1e20)
	b = randmatrix(5, 1, min=-1000, max=1000)
	x1 = lu_solve(A, b) + randmatrix(5, 1, min=-1e-5, max=1.e-5)
	x2 = improve_solution(A, x1, b)
	assert norm(residual(A, x2, b), 2) < norm(residual(A, x1, b), 2)

	def test_exp_pade():
	for i in range(3):
	dps = 15
	extra = 15
	mp.dps = dps + extra
	dm = 0
	N = 3
	dg = range(1,N+1)
	a = diag(dg)
	expa = diag([exp(x) for x in dg])
	# choose a random matrix not close to be singular
	# to avoid adding too much extra precision in computing
	# m*-1 M * m
	while abs(dm) < 0.01:
	m = randmatrix(N)
	dm = det(m)
	m = m/dm
	a1 = m*-1 a * m
	e2 = m*-1 expa * m
	mp.dps = dps
	e1 = expm(a1, method='pade')
	mp.dps = dps + extra
	d = e2 - e1
	#print d
	mp.dps = dps
	assert norm(d, inf).ae(0)
	mp.dps = 15

	def test_qr():
	mp.dps = 15 # used default value for dps
	lowlimit = -9 # lower limit of matrix element value
	uplimit = 9 # uppter limit of matrix element value
	maxm = 4 # max matrix size
	flg = False # toggle to create real vs complex matrix
	zero = mpf('0.0')

	for k in xrange(0,10):
	exdps = 0
	mode = 'full'
	flg = bool(k % 2)

	# generate arbitrary matrix size (2 to maxm)
	num1 = nint(maxm*rand())
	num2 = nint(maxm*rand())
	m = int(max(num1, num2))
	n = int(min(num1, num2))

	# create matrix
	A = mp.matrix(m,n)

	# populate matrix values with arbitrary integers
	if flg:
	flg = False
	dtype = 'complex'
	for j in xrange(0,n):
	for i in xrange(0,m):
	val = nint(lowlimit + (uplimit-lowlimit)*rand())
	val2 = nint(lowlimit + (uplimit-lowlimit)*rand())
	A[i,j] = mpc(val, val2)
	else:
	flg = True
	dtype = 'real'
	for j in xrange(0,n):
	for i in xrange(0,m):
	val = nint(lowlimit + (uplimit-lowlimit)*rand())
	A[i,j] = mpf(val)

	# perform A -> QR decomposition
	Q, R = qr(A, mode, edps = exdps)

	#print('\n\n A = \n', nstr(A, 4))
	#print('\n Q = \n', nstr(Q, 4))
	#print('\n R = \n', nstr(R, 4))
	#print('\n QR = \n', nstr(QR, 4))

	maxnorm = mpf('1.0E-11')
	n1 = norm(A - Q * R)
	#print '\n Norm of A - Q * R = ', n1
	assert n1 <= maxnorm

	if dtype == 'real':
	n1 = norm(eye(m) - Q.T * Q)
	#print ' Norm of I - Q.T * Q = ', n1
	assert n1 <= maxnorm

	n1 = norm(eye(m) - Q * Q.T)
	#print ' Norm of I - Q * Q.T = ', n1
	assert n1 <= maxnorm

	if dtype == 'complex':
	n1 = norm(eye(m) - Q.T * Q.conjugate())
	#print ' Norm of I - Q.T * Q.conjugate() = ', n1
	assert n1 <= maxnorm

	n1 = norm(eye(m) - Q.conjugate() * Q.T)
	#print ' Norm of I - Q.conjugate() * Q.T = ', n1
	assert n1 <= maxnorm