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using for loop to install conda package

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ton
2023-04-16 11:03:27 +07:00
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import pytest
import numpy as np
from numpy.testing import assert_allclose
from scipy.integrate import quad_vec
from multiprocessing.dummy import Pool
quadrature_params = pytest.mark.parametrize(
'quadrature', [None, "gk15", "gk21", "trapezoid"])
@quadrature_params
def test_quad_vec_simple(quadrature):
n = np.arange(10)
f = lambda x: x**n
for epsabs in [0.1, 1e-3, 1e-6]:
if quadrature == 'trapezoid' and epsabs < 1e-4:
# slow: skip
continue
kwargs = dict(epsabs=epsabs, quadrature=quadrature)
exact = 2**(n+1)/(n + 1)
res, err = quad_vec(f, 0, 2, norm='max', **kwargs)
assert_allclose(res, exact, rtol=0, atol=epsabs)
res, err = quad_vec(f, 0, 2, norm='2', **kwargs)
assert np.linalg.norm(res - exact) < epsabs
res, err = quad_vec(f, 0, 2, norm='max', points=(0.5, 1.0), **kwargs)
assert_allclose(res, exact, rtol=0, atol=epsabs)
res, err, *rest = quad_vec(f, 0, 2, norm='max',
epsrel=1e-8,
full_output=True,
limit=10000,
**kwargs)
assert_allclose(res, exact, rtol=0, atol=epsabs)
@quadrature_params
def test_quad_vec_simple_inf(quadrature):
f = lambda x: 1 / (1 + np.float64(x)**2)
for epsabs in [0.1, 1e-3, 1e-6]:
if quadrature == 'trapezoid' and epsabs < 1e-4:
# slow: skip
continue
kwargs = dict(norm='max', epsabs=epsabs, quadrature=quadrature)
res, err = quad_vec(f, 0, np.inf, **kwargs)
assert_allclose(res, np.pi/2, rtol=0, atol=max(epsabs, err))
res, err = quad_vec(f, 0, -np.inf, **kwargs)
assert_allclose(res, -np.pi/2, rtol=0, atol=max(epsabs, err))
res, err = quad_vec(f, -np.inf, 0, **kwargs)
assert_allclose(res, np.pi/2, rtol=0, atol=max(epsabs, err))
res, err = quad_vec(f, np.inf, 0, **kwargs)
assert_allclose(res, -np.pi/2, rtol=0, atol=max(epsabs, err))
res, err = quad_vec(f, -np.inf, np.inf, **kwargs)
assert_allclose(res, np.pi, rtol=0, atol=max(epsabs, err))
res, err = quad_vec(f, np.inf, -np.inf, **kwargs)
assert_allclose(res, -np.pi, rtol=0, atol=max(epsabs, err))
res, err = quad_vec(f, np.inf, np.inf, **kwargs)
assert_allclose(res, 0, rtol=0, atol=max(epsabs, err))
res, err = quad_vec(f, -np.inf, -np.inf, **kwargs)
assert_allclose(res, 0, rtol=0, atol=max(epsabs, err))
res, err = quad_vec(f, 0, np.inf, points=(1.0, 2.0), **kwargs)
assert_allclose(res, np.pi/2, rtol=0, atol=max(epsabs, err))
f = lambda x: np.sin(x + 2) / (1 + x**2)
exact = np.pi / np.e * np.sin(2)
epsabs = 1e-5
res, err, info = quad_vec(f, -np.inf, np.inf, limit=1000, norm='max', epsabs=epsabs,
quadrature=quadrature, full_output=True)
assert info.status == 1
assert_allclose(res, exact, rtol=0, atol=max(epsabs, 1.5 * err))
def test_quad_vec_args():
f = lambda x, a: x * (x + a) * np.arange(3)
a = 2
exact = np.array([0, 4/3, 8/3])
res, err = quad_vec(f, 0, 1, args=(a,))
assert_allclose(res, exact, rtol=0, atol=1e-4)
def _lorenzian(x):
return 1 / (1 + x**2)
def test_quad_vec_pool():
f = _lorenzian
res, err = quad_vec(f, -np.inf, np.inf, norm='max', epsabs=1e-4, workers=4)
assert_allclose(res, np.pi, rtol=0, atol=1e-4)
with Pool(10) as pool:
f = lambda x: 1 / (1 + x**2)
res, err = quad_vec(f, -np.inf, np.inf, norm='max', epsabs=1e-4, workers=pool.map)
assert_allclose(res, np.pi, rtol=0, atol=1e-4)
def _func_with_args(x, a):
return x * (x + a) * np.arange(3)
@pytest.mark.parametrize('extra_args', [2, (2,)])
@pytest.mark.parametrize('workers', [1, 10])
def test_quad_vec_pool_args(extra_args, workers):
f = _func_with_args
exact = np.array([0, 4/3, 8/3])
res, err = quad_vec(f, 0, 1, args=extra_args, workers=workers)
assert_allclose(res, exact, rtol=0, atol=1e-4)
with Pool(workers) as pool:
res, err = quad_vec(f, 0, 1, args=extra_args, workers=pool.map)
assert_allclose(res, exact, rtol=0, atol=1e-4)
@quadrature_params
def test_num_eval(quadrature):
def f(x):
count[0] += 1
return x**5
count = [0]
res = quad_vec(f, 0, 1, norm='max', full_output=True, quadrature=quadrature)
assert res[2].neval == count[0]
def test_info():
def f(x):
return np.ones((3, 2, 1))
res, err, info = quad_vec(f, 0, 1, norm='max', full_output=True)
assert info.success == True
assert info.status == 0
assert info.message == 'Target precision reached.'
assert info.neval > 0
assert info.intervals.shape[1] == 2
assert info.integrals.shape == (info.intervals.shape[0], 3, 2, 1)
assert info.errors.shape == (info.intervals.shape[0],)
def test_nan_inf():
def f_nan(x):
return np.nan
def f_inf(x):
return np.inf if x < 0.1 else 1/x
res, err, info = quad_vec(f_nan, 0, 1, full_output=True)
assert info.status == 3
res, err, info = quad_vec(f_inf, 0, 1, full_output=True)
assert info.status == 3
@pytest.mark.parametrize('a,b', [(0, 1), (0, np.inf), (np.inf, 0),
(-np.inf, np.inf), (np.inf, -np.inf)])
def test_points(a, b):
# Check that initial interval splitting is done according to
# `points`, by checking that consecutive sets of 15 point (for
# gk15) function evaluations lie between `points`
points = (0, 0.25, 0.5, 0.75, 1.0)
points += tuple(-x for x in points)
quadrature_points = 15
interval_sets = []
count = 0
def f(x):
nonlocal count
if count % quadrature_points == 0:
interval_sets.append(set())
count += 1
interval_sets[-1].add(float(x))
return 0.0
quad_vec(f, a, b, points=points, quadrature='gk15', limit=0)
# Check that all point sets lie in a single `points` interval
for p in interval_sets:
j = np.searchsorted(sorted(points), tuple(p))
assert np.all(j == j[0])

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import itertools
import numpy as np
from numpy.testing import assert_allclose
from scipy.integrate import ode
def _band_count(a):
"""Returns ml and mu, the lower and upper band sizes of a."""
nrows, ncols = a.shape
ml = 0
for k in range(-nrows+1, 0):
if np.diag(a, k).any():
ml = -k
break
mu = 0
for k in range(nrows-1, 0, -1):
if np.diag(a, k).any():
mu = k
break
return ml, mu
def _linear_func(t, y, a):
"""Linear system dy/dt = a * y"""
return a.dot(y)
def _linear_jac(t, y, a):
"""Jacobian of a * y is a."""
return a
def _linear_banded_jac(t, y, a):
"""Banded Jacobian."""
ml, mu = _band_count(a)
bjac = [np.r_[[0] * k, np.diag(a, k)] for k in range(mu, 0, -1)]
bjac.append(np.diag(a))
for k in range(-1, -ml-1, -1):
bjac.append(np.r_[np.diag(a, k), [0] * (-k)])
return bjac
def _solve_linear_sys(a, y0, tend=1, dt=0.1,
solver=None, method='bdf', use_jac=True,
with_jacobian=False, banded=False):
"""Use scipy.integrate.ode to solve a linear system of ODEs.
a : square ndarray
Matrix of the linear system to be solved.
y0 : ndarray
Initial condition
tend : float
Stop time.
dt : float
Step size of the output.
solver : str
If not None, this must be "vode", "lsoda" or "zvode".
method : str
Either "bdf" or "adams".
use_jac : bool
Determines if the jacobian function is passed to ode().
with_jacobian : bool
Passed to ode.set_integrator().
banded : bool
Determines whether a banded or full jacobian is used.
If `banded` is True, `lband` and `uband` are determined by the
values in `a`.
"""
if banded:
lband, uband = _band_count(a)
else:
lband = None
uband = None
if use_jac:
if banded:
r = ode(_linear_func, _linear_banded_jac)
else:
r = ode(_linear_func, _linear_jac)
else:
r = ode(_linear_func)
if solver is None:
if np.iscomplexobj(a):
solver = "zvode"
else:
solver = "vode"
r.set_integrator(solver,
with_jacobian=with_jacobian,
method=method,
lband=lband, uband=uband,
rtol=1e-9, atol=1e-10,
)
t0 = 0
r.set_initial_value(y0, t0)
r.set_f_params(a)
r.set_jac_params(a)
t = [t0]
y = [y0]
while r.successful() and r.t < tend:
r.integrate(r.t + dt)
t.append(r.t)
y.append(r.y)
t = np.array(t)
y = np.array(y)
return t, y
def _analytical_solution(a, y0, t):
"""
Analytical solution to the linear differential equations dy/dt = a*y.
The solution is only valid if `a` is diagonalizable.
Returns a 2-D array with shape (len(t), len(y0)).
"""
lam, v = np.linalg.eig(a)
c = np.linalg.solve(v, y0)
e = c * np.exp(lam * t.reshape(-1, 1))
sol = e.dot(v.T)
return sol
def test_banded_ode_solvers():
# Test the "lsoda", "vode" and "zvode" solvers of the `ode` class
# with a system that has a banded Jacobian matrix.
t_exact = np.linspace(0, 1.0, 5)
# --- Real arrays for testing the "lsoda" and "vode" solvers ---
# lband = 2, uband = 1:
a_real = np.array([[-0.6, 0.1, 0.0, 0.0, 0.0],
[0.2, -0.5, 0.9, 0.0, 0.0],
[0.1, 0.1, -0.4, 0.1, 0.0],
[0.0, 0.3, -0.1, -0.9, -0.3],
[0.0, 0.0, 0.1, 0.1, -0.7]])
# lband = 0, uband = 1:
a_real_upper = np.triu(a_real)
# lband = 2, uband = 0:
a_real_lower = np.tril(a_real)
# lband = 0, uband = 0:
a_real_diag = np.triu(a_real_lower)
real_matrices = [a_real, a_real_upper, a_real_lower, a_real_diag]
real_solutions = []
for a in real_matrices:
y0 = np.arange(1, a.shape[0] + 1)
y_exact = _analytical_solution(a, y0, t_exact)
real_solutions.append((y0, t_exact, y_exact))
def check_real(idx, solver, meth, use_jac, with_jac, banded):
a = real_matrices[idx]
y0, t_exact, y_exact = real_solutions[idx]
t, y = _solve_linear_sys(a, y0,
tend=t_exact[-1],
dt=t_exact[1] - t_exact[0],
solver=solver,
method=meth,
use_jac=use_jac,
with_jacobian=with_jac,
banded=banded)
assert_allclose(t, t_exact)
assert_allclose(y, y_exact)
for idx in range(len(real_matrices)):
p = [['vode', 'lsoda'], # solver
['bdf', 'adams'], # method
[False, True], # use_jac
[False, True], # with_jacobian
[False, True]] # banded
for solver, meth, use_jac, with_jac, banded in itertools.product(*p):
check_real(idx, solver, meth, use_jac, with_jac, banded)
# --- Complex arrays for testing the "zvode" solver ---
# complex, lband = 2, uband = 1:
a_complex = a_real - 0.5j * a_real
# complex, lband = 0, uband = 0:
a_complex_diag = np.diag(np.diag(a_complex))
complex_matrices = [a_complex, a_complex_diag]
complex_solutions = []
for a in complex_matrices:
y0 = np.arange(1, a.shape[0] + 1) + 1j
y_exact = _analytical_solution(a, y0, t_exact)
complex_solutions.append((y0, t_exact, y_exact))
def check_complex(idx, solver, meth, use_jac, with_jac, banded):
a = complex_matrices[idx]
y0, t_exact, y_exact = complex_solutions[idx]
t, y = _solve_linear_sys(a, y0,
tend=t_exact[-1],
dt=t_exact[1] - t_exact[0],
solver=solver,
method=meth,
use_jac=use_jac,
with_jacobian=with_jac,
banded=banded)
assert_allclose(t, t_exact)
assert_allclose(y, y_exact)
for idx in range(len(complex_matrices)):
p = [['bdf', 'adams'], # method
[False, True], # use_jac
[False, True], # with_jacobian
[False, True]] # banded
for meth, use_jac, with_jac, banded in itertools.product(*p):
check_complex(idx, "zvode", meth, use_jac, with_jac, banded)

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import sys
try:
from StringIO import StringIO
except ImportError:
from io import StringIO
import numpy as np
from numpy.testing import (assert_, assert_array_equal, assert_allclose,
assert_equal)
from pytest import raises as assert_raises
from scipy.sparse import coo_matrix
from scipy.special import erf
from scipy.integrate._bvp import (modify_mesh, estimate_fun_jac,
estimate_bc_jac, compute_jac_indices,
construct_global_jac, solve_bvp)
def exp_fun(x, y):
return np.vstack((y[1], y[0]))
def exp_fun_jac(x, y):
df_dy = np.empty((2, 2, x.shape[0]))
df_dy[0, 0] = 0
df_dy[0, 1] = 1
df_dy[1, 0] = 1
df_dy[1, 1] = 0
return df_dy
def exp_bc(ya, yb):
return np.hstack((ya[0] - 1, yb[0]))
def exp_bc_complex(ya, yb):
return np.hstack((ya[0] - 1 - 1j, yb[0]))
def exp_bc_jac(ya, yb):
dbc_dya = np.array([
[1, 0],
[0, 0]
])
dbc_dyb = np.array([
[0, 0],
[1, 0]
])
return dbc_dya, dbc_dyb
def exp_sol(x):
return (np.exp(-x) - np.exp(x - 2)) / (1 - np.exp(-2))
def sl_fun(x, y, p):
return np.vstack((y[1], -p[0]**2 * y[0]))
def sl_fun_jac(x, y, p):
n, m = y.shape
df_dy = np.empty((n, 2, m))
df_dy[0, 0] = 0
df_dy[0, 1] = 1
df_dy[1, 0] = -p[0]**2
df_dy[1, 1] = 0
df_dp = np.empty((n, 1, m))
df_dp[0, 0] = 0
df_dp[1, 0] = -2 * p[0] * y[0]
return df_dy, df_dp
def sl_bc(ya, yb, p):
return np.hstack((ya[0], yb[0], ya[1] - p[0]))
def sl_bc_jac(ya, yb, p):
dbc_dya = np.zeros((3, 2))
dbc_dya[0, 0] = 1
dbc_dya[2, 1] = 1
dbc_dyb = np.zeros((3, 2))
dbc_dyb[1, 0] = 1
dbc_dp = np.zeros((3, 1))
dbc_dp[2, 0] = -1
return dbc_dya, dbc_dyb, dbc_dp
def sl_sol(x, p):
return np.sin(p[0] * x)
def emden_fun(x, y):
return np.vstack((y[1], -y[0]**5))
def emden_fun_jac(x, y):
df_dy = np.empty((2, 2, x.shape[0]))
df_dy[0, 0] = 0
df_dy[0, 1] = 1
df_dy[1, 0] = -5 * y[0]**4
df_dy[1, 1] = 0
return df_dy
def emden_bc(ya, yb):
return np.array([ya[1], yb[0] - (3/4)**0.5])
def emden_bc_jac(ya, yb):
dbc_dya = np.array([
[0, 1],
[0, 0]
])
dbc_dyb = np.array([
[0, 0],
[1, 0]
])
return dbc_dya, dbc_dyb
def emden_sol(x):
return (1 + x**2/3)**-0.5
def undefined_fun(x, y):
return np.zeros_like(y)
def undefined_bc(ya, yb):
return np.array([ya[0], yb[0] - 1])
def big_fun(x, y):
f = np.zeros_like(y)
f[::2] = y[1::2]
return f
def big_bc(ya, yb):
return np.hstack((ya[::2], yb[::2] - 1))
def big_sol(x, n):
y = np.ones((2 * n, x.size))
y[::2] = x
return x
def big_fun_with_parameters(x, y, p):
""" Big version of sl_fun, with two parameters.
The two differential equations represented by sl_fun are broadcast to the
number of rows of y, rotating between the parameters p[0] and p[1].
Here are the differential equations:
dy[0]/dt = y[1]
dy[1]/dt = -p[0]**2 * y[0]
dy[2]/dt = y[3]
dy[3]/dt = -p[1]**2 * y[2]
dy[4]/dt = y[5]
dy[5]/dt = -p[0]**2 * y[4]
dy[6]/dt = y[7]
dy[7]/dt = -p[1]**2 * y[6]
.
.
.
"""
f = np.zeros_like(y)
f[::2] = y[1::2]
f[1::4] = -p[0]**2 * y[::4]
f[3::4] = -p[1]**2 * y[2::4]
return f
def big_fun_with_parameters_jac(x, y, p):
# big version of sl_fun_jac, with two parameters
n, m = y.shape
df_dy = np.zeros((n, n, m))
df_dy[range(0, n, 2), range(1, n, 2)] = 1
df_dy[range(1, n, 4), range(0, n, 4)] = -p[0]**2
df_dy[range(3, n, 4), range(2, n, 4)] = -p[1]**2
df_dp = np.zeros((n, 2, m))
df_dp[range(1, n, 4), 0] = -2 * p[0] * y[range(0, n, 4)]
df_dp[range(3, n, 4), 1] = -2 * p[1] * y[range(2, n, 4)]
return df_dy, df_dp
def big_bc_with_parameters(ya, yb, p):
# big version of sl_bc, with two parameters
return np.hstack((ya[::2], yb[::2], ya[1] - p[0], ya[3] - p[1]))
def big_bc_with_parameters_jac(ya, yb, p):
# big version of sl_bc_jac, with two parameters
n = ya.shape[0]
dbc_dya = np.zeros((n + 2, n))
dbc_dyb = np.zeros((n + 2, n))
dbc_dya[range(n // 2), range(0, n, 2)] = 1
dbc_dyb[range(n // 2, n), range(0, n, 2)] = 1
dbc_dp = np.zeros((n + 2, 2))
dbc_dp[n, 0] = -1
dbc_dya[n, 1] = 1
dbc_dp[n + 1, 1] = -1
dbc_dya[n + 1, 3] = 1
return dbc_dya, dbc_dyb, dbc_dp
def big_sol_with_parameters(x, p):
# big version of sl_sol, with two parameters
return np.vstack((np.sin(p[0] * x), np.sin(p[1] * x)))
def shock_fun(x, y):
eps = 1e-3
return np.vstack((
y[1],
-(x * y[1] + eps * np.pi**2 * np.cos(np.pi * x) +
np.pi * x * np.sin(np.pi * x)) / eps
))
def shock_bc(ya, yb):
return np.array([ya[0] + 2, yb[0]])
def shock_sol(x):
eps = 1e-3
k = np.sqrt(2 * eps)
return np.cos(np.pi * x) + erf(x / k) / erf(1 / k)
def nonlin_bc_fun(x, y):
# laplace eq.
return np.stack([y[1], np.zeros_like(x)])
def nonlin_bc_bc(ya, yb):
phiA, phipA = ya
phiC, phipC = yb
kappa, ioA, ioC, V, f = 1.64, 0.01, 1.0e-4, 0.5, 38.9
# Butler-Volmer Kinetics at Anode
hA = 0.0-phiA-0.0
iA = ioA * (np.exp(f*hA) - np.exp(-f*hA))
res0 = iA + kappa * phipA
# Butler-Volmer Kinetics at Cathode
hC = V - phiC - 1.0
iC = ioC * (np.exp(f*hC) - np.exp(-f*hC))
res1 = iC - kappa*phipC
return np.array([res0, res1])
def nonlin_bc_sol(x):
return -0.13426436116763119 - 1.1308709 * x
def test_modify_mesh():
x = np.array([0, 1, 3, 9], dtype=float)
x_new = modify_mesh(x, np.array([0]), np.array([2]))
assert_array_equal(x_new, np.array([0, 0.5, 1, 3, 5, 7, 9]))
x = np.array([-6, -3, 0, 3, 6], dtype=float)
x_new = modify_mesh(x, np.array([1], dtype=int), np.array([0, 2, 3]))
assert_array_equal(x_new, [-6, -5, -4, -3, -1.5, 0, 1, 2, 3, 4, 5, 6])
def test_compute_fun_jac():
x = np.linspace(0, 1, 5)
y = np.empty((2, x.shape[0]))
y[0] = 0.01
y[1] = 0.02
p = np.array([])
df_dy, df_dp = estimate_fun_jac(lambda x, y, p: exp_fun(x, y), x, y, p)
df_dy_an = exp_fun_jac(x, y)
assert_allclose(df_dy, df_dy_an)
assert_(df_dp is None)
x = np.linspace(0, np.pi, 5)
y = np.empty((2, x.shape[0]))
y[0] = np.sin(x)
y[1] = np.cos(x)
p = np.array([1.0])
df_dy, df_dp = estimate_fun_jac(sl_fun, x, y, p)
df_dy_an, df_dp_an = sl_fun_jac(x, y, p)
assert_allclose(df_dy, df_dy_an)
assert_allclose(df_dp, df_dp_an)
x = np.linspace(0, 1, 10)
y = np.empty((2, x.shape[0]))
y[0] = (3/4)**0.5
y[1] = 1e-4
p = np.array([])
df_dy, df_dp = estimate_fun_jac(lambda x, y, p: emden_fun(x, y), x, y, p)
df_dy_an = emden_fun_jac(x, y)
assert_allclose(df_dy, df_dy_an)
assert_(df_dp is None)
def test_compute_bc_jac():
ya = np.array([-1.0, 2])
yb = np.array([0.5, 3])
p = np.array([])
dbc_dya, dbc_dyb, dbc_dp = estimate_bc_jac(
lambda ya, yb, p: exp_bc(ya, yb), ya, yb, p)
dbc_dya_an, dbc_dyb_an = exp_bc_jac(ya, yb)
assert_allclose(dbc_dya, dbc_dya_an)
assert_allclose(dbc_dyb, dbc_dyb_an)
assert_(dbc_dp is None)
ya = np.array([0.0, 1])
yb = np.array([0.0, -1])
p = np.array([0.5])
dbc_dya, dbc_dyb, dbc_dp = estimate_bc_jac(sl_bc, ya, yb, p)
dbc_dya_an, dbc_dyb_an, dbc_dp_an = sl_bc_jac(ya, yb, p)
assert_allclose(dbc_dya, dbc_dya_an)
assert_allclose(dbc_dyb, dbc_dyb_an)
assert_allclose(dbc_dp, dbc_dp_an)
ya = np.array([0.5, 100])
yb = np.array([-1000, 10.5])
p = np.array([])
dbc_dya, dbc_dyb, dbc_dp = estimate_bc_jac(
lambda ya, yb, p: emden_bc(ya, yb), ya, yb, p)
dbc_dya_an, dbc_dyb_an = emden_bc_jac(ya, yb)
assert_allclose(dbc_dya, dbc_dya_an)
assert_allclose(dbc_dyb, dbc_dyb_an)
assert_(dbc_dp is None)
def test_compute_jac_indices():
n = 2
m = 4
k = 2
i, j = compute_jac_indices(n, m, k)
s = coo_matrix((np.ones_like(i), (i, j))).toarray()
s_true = np.array([
[1, 1, 1, 1, 0, 0, 0, 0, 1, 1],
[1, 1, 1, 1, 0, 0, 0, 0, 1, 1],
[0, 0, 1, 1, 1, 1, 0, 0, 1, 1],
[0, 0, 1, 1, 1, 1, 0, 0, 1, 1],
[0, 0, 0, 0, 1, 1, 1, 1, 1, 1],
[0, 0, 0, 0, 1, 1, 1, 1, 1, 1],
[1, 1, 0, 0, 0, 0, 1, 1, 1, 1],
[1, 1, 0, 0, 0, 0, 1, 1, 1, 1],
[1, 1, 0, 0, 0, 0, 1, 1, 1, 1],
[1, 1, 0, 0, 0, 0, 1, 1, 1, 1],
])
assert_array_equal(s, s_true)
def test_compute_global_jac():
n = 2
m = 5
k = 1
i_jac, j_jac = compute_jac_indices(2, 5, 1)
x = np.linspace(0, 1, 5)
h = np.diff(x)
y = np.vstack((np.sin(np.pi * x), np.pi * np.cos(np.pi * x)))
p = np.array([3.0])
f = sl_fun(x, y, p)
x_middle = x[:-1] + 0.5 * h
y_middle = 0.5 * (y[:, :-1] + y[:, 1:]) - h/8 * (f[:, 1:] - f[:, :-1])
df_dy, df_dp = sl_fun_jac(x, y, p)
df_dy_middle, df_dp_middle = sl_fun_jac(x_middle, y_middle, p)
dbc_dya, dbc_dyb, dbc_dp = sl_bc_jac(y[:, 0], y[:, -1], p)
J = construct_global_jac(n, m, k, i_jac, j_jac, h, df_dy, df_dy_middle,
df_dp, df_dp_middle, dbc_dya, dbc_dyb, dbc_dp)
J = J.toarray()
def J_block(h, p):
return np.array([
[h**2*p**2/12 - 1, -0.5*h, -h**2*p**2/12 + 1, -0.5*h],
[0.5*h*p**2, h**2*p**2/12 - 1, 0.5*h*p**2, 1 - h**2*p**2/12]
])
J_true = np.zeros((m * n + k, m * n + k))
for i in range(m - 1):
J_true[i * n: (i + 1) * n, i * n: (i + 2) * n] = J_block(h[i], p[0])
J_true[:(m - 1) * n:2, -1] = p * h**2/6 * (y[0, :-1] - y[0, 1:])
J_true[1:(m - 1) * n:2, -1] = p * (h * (y[0, :-1] + y[0, 1:]) +
h**2/6 * (y[1, :-1] - y[1, 1:]))
J_true[8, 0] = 1
J_true[9, 8] = 1
J_true[10, 1] = 1
J_true[10, 10] = -1
assert_allclose(J, J_true, rtol=1e-10)
df_dy, df_dp = estimate_fun_jac(sl_fun, x, y, p)
df_dy_middle, df_dp_middle = estimate_fun_jac(sl_fun, x_middle, y_middle, p)
dbc_dya, dbc_dyb, dbc_dp = estimate_bc_jac(sl_bc, y[:, 0], y[:, -1], p)
J = construct_global_jac(n, m, k, i_jac, j_jac, h, df_dy, df_dy_middle,
df_dp, df_dp_middle, dbc_dya, dbc_dyb, dbc_dp)
J = J.toarray()
assert_allclose(J, J_true, rtol=2e-8, atol=2e-8)
def test_parameter_validation():
x = [0, 1, 0.5]
y = np.zeros((2, 3))
assert_raises(ValueError, solve_bvp, exp_fun, exp_bc, x, y)
x = np.linspace(0, 1, 5)
y = np.zeros((2, 4))
assert_raises(ValueError, solve_bvp, exp_fun, exp_bc, x, y)
fun = lambda x, y, p: exp_fun(x, y)
bc = lambda ya, yb, p: exp_bc(ya, yb)
y = np.zeros((2, x.shape[0]))
assert_raises(ValueError, solve_bvp, fun, bc, x, y, p=[1])
def wrong_shape_fun(x, y):
return np.zeros(3)
assert_raises(ValueError, solve_bvp, wrong_shape_fun, bc, x, y)
S = np.array([[0, 0]])
assert_raises(ValueError, solve_bvp, exp_fun, exp_bc, x, y, S=S)
def test_no_params():
x = np.linspace(0, 1, 5)
x_test = np.linspace(0, 1, 100)
y = np.zeros((2, x.shape[0]))
for fun_jac in [None, exp_fun_jac]:
for bc_jac in [None, exp_bc_jac]:
sol = solve_bvp(exp_fun, exp_bc, x, y, fun_jac=fun_jac,
bc_jac=bc_jac)
assert_equal(sol.status, 0)
assert_(sol.success)
assert_equal(sol.x.size, 5)
sol_test = sol.sol(x_test)
assert_allclose(sol_test[0], exp_sol(x_test), atol=1e-5)
f_test = exp_fun(x_test, sol_test)
r = sol.sol(x_test, 1) - f_test
rel_res = r / (1 + np.abs(f_test))
norm_res = np.sum(rel_res**2, axis=0)**0.5
assert_(np.all(norm_res < 1e-3))
assert_(np.all(sol.rms_residuals < 1e-3))
assert_allclose(sol.sol(sol.x), sol.y, rtol=1e-10, atol=1e-10)
assert_allclose(sol.sol(sol.x, 1), sol.yp, rtol=1e-10, atol=1e-10)
def test_with_params():
x = np.linspace(0, np.pi, 5)
x_test = np.linspace(0, np.pi, 100)
y = np.ones((2, x.shape[0]))
for fun_jac in [None, sl_fun_jac]:
for bc_jac in [None, sl_bc_jac]:
sol = solve_bvp(sl_fun, sl_bc, x, y, p=[0.5], fun_jac=fun_jac,
bc_jac=bc_jac)
assert_equal(sol.status, 0)
assert_(sol.success)
assert_(sol.x.size < 10)
assert_allclose(sol.p, [1], rtol=1e-4)
sol_test = sol.sol(x_test)
assert_allclose(sol_test[0], sl_sol(x_test, [1]),
rtol=1e-4, atol=1e-4)
f_test = sl_fun(x_test, sol_test, [1])
r = sol.sol(x_test, 1) - f_test
rel_res = r / (1 + np.abs(f_test))
norm_res = np.sum(rel_res ** 2, axis=0) ** 0.5
assert_(np.all(norm_res < 1e-3))
assert_(np.all(sol.rms_residuals < 1e-3))
assert_allclose(sol.sol(sol.x), sol.y, rtol=1e-10, atol=1e-10)
assert_allclose(sol.sol(sol.x, 1), sol.yp, rtol=1e-10, atol=1e-10)
def test_singular_term():
x = np.linspace(0, 1, 10)
x_test = np.linspace(0.05, 1, 100)
y = np.empty((2, 10))
y[0] = (3/4)**0.5
y[1] = 1e-4
S = np.array([[0, 0], [0, -2]])
for fun_jac in [None, emden_fun_jac]:
for bc_jac in [None, emden_bc_jac]:
sol = solve_bvp(emden_fun, emden_bc, x, y, S=S, fun_jac=fun_jac,
bc_jac=bc_jac)
assert_equal(sol.status, 0)
assert_(sol.success)
assert_equal(sol.x.size, 10)
sol_test = sol.sol(x_test)
assert_allclose(sol_test[0], emden_sol(x_test), atol=1e-5)
f_test = emden_fun(x_test, sol_test) + S.dot(sol_test) / x_test
r = sol.sol(x_test, 1) - f_test
rel_res = r / (1 + np.abs(f_test))
norm_res = np.sum(rel_res ** 2, axis=0) ** 0.5
assert_(np.all(norm_res < 1e-3))
assert_allclose(sol.sol(sol.x), sol.y, rtol=1e-10, atol=1e-10)
assert_allclose(sol.sol(sol.x, 1), sol.yp, rtol=1e-10, atol=1e-10)
def test_complex():
# The test is essentially the same as test_no_params, but boundary
# conditions are turned into complex.
x = np.linspace(0, 1, 5)
x_test = np.linspace(0, 1, 100)
y = np.zeros((2, x.shape[0]), dtype=complex)
for fun_jac in [None, exp_fun_jac]:
for bc_jac in [None, exp_bc_jac]:
sol = solve_bvp(exp_fun, exp_bc_complex, x, y, fun_jac=fun_jac,
bc_jac=bc_jac)
assert_equal(sol.status, 0)
assert_(sol.success)
sol_test = sol.sol(x_test)
assert_allclose(sol_test[0].real, exp_sol(x_test), atol=1e-5)
assert_allclose(sol_test[0].imag, exp_sol(x_test), atol=1e-5)
f_test = exp_fun(x_test, sol_test)
r = sol.sol(x_test, 1) - f_test
rel_res = r / (1 + np.abs(f_test))
norm_res = np.sum(np.real(rel_res * np.conj(rel_res)),
axis=0) ** 0.5
assert_(np.all(norm_res < 1e-3))
assert_(np.all(sol.rms_residuals < 1e-3))
assert_allclose(sol.sol(sol.x), sol.y, rtol=1e-10, atol=1e-10)
assert_allclose(sol.sol(sol.x, 1), sol.yp, rtol=1e-10, atol=1e-10)
def test_failures():
x = np.linspace(0, 1, 2)
y = np.zeros((2, x.size))
res = solve_bvp(exp_fun, exp_bc, x, y, tol=1e-5, max_nodes=5)
assert_equal(res.status, 1)
assert_(not res.success)
x = np.linspace(0, 1, 5)
y = np.zeros((2, x.size))
res = solve_bvp(undefined_fun, undefined_bc, x, y)
assert_equal(res.status, 2)
assert_(not res.success)
def test_big_problem():
n = 30
x = np.linspace(0, 1, 5)
y = np.zeros((2 * n, x.size))
sol = solve_bvp(big_fun, big_bc, x, y)
assert_equal(sol.status, 0)
assert_(sol.success)
sol_test = sol.sol(x)
assert_allclose(sol_test[0], big_sol(x, n))
f_test = big_fun(x, sol_test)
r = sol.sol(x, 1) - f_test
rel_res = r / (1 + np.abs(f_test))
norm_res = np.sum(np.real(rel_res * np.conj(rel_res)), axis=0) ** 0.5
assert_(np.all(norm_res < 1e-3))
assert_(np.all(sol.rms_residuals < 1e-3))
assert_allclose(sol.sol(sol.x), sol.y, rtol=1e-10, atol=1e-10)
assert_allclose(sol.sol(sol.x, 1), sol.yp, rtol=1e-10, atol=1e-10)
def test_big_problem_with_parameters():
n = 30
x = np.linspace(0, np.pi, 5)
x_test = np.linspace(0, np.pi, 100)
y = np.ones((2 * n, x.size))
for fun_jac in [None, big_fun_with_parameters_jac]:
for bc_jac in [None, big_bc_with_parameters_jac]:
sol = solve_bvp(big_fun_with_parameters, big_bc_with_parameters, x,
y, p=[0.5, 0.5], fun_jac=fun_jac, bc_jac=bc_jac)
assert_equal(sol.status, 0)
assert_(sol.success)
assert_allclose(sol.p, [1, 1], rtol=1e-4)
sol_test = sol.sol(x_test)
for isol in range(0, n, 4):
assert_allclose(sol_test[isol],
big_sol_with_parameters(x_test, [1, 1])[0],
rtol=1e-4, atol=1e-4)
assert_allclose(sol_test[isol + 2],
big_sol_with_parameters(x_test, [1, 1])[1],
rtol=1e-4, atol=1e-4)
f_test = big_fun_with_parameters(x_test, sol_test, [1, 1])
r = sol.sol(x_test, 1) - f_test
rel_res = r / (1 + np.abs(f_test))
norm_res = np.sum(rel_res ** 2, axis=0) ** 0.5
assert_(np.all(norm_res < 1e-3))
assert_(np.all(sol.rms_residuals < 1e-3))
assert_allclose(sol.sol(sol.x), sol.y, rtol=1e-10, atol=1e-10)
assert_allclose(sol.sol(sol.x, 1), sol.yp, rtol=1e-10, atol=1e-10)
def test_shock_layer():
x = np.linspace(-1, 1, 5)
x_test = np.linspace(-1, 1, 100)
y = np.zeros((2, x.size))
sol = solve_bvp(shock_fun, shock_bc, x, y)
assert_equal(sol.status, 0)
assert_(sol.success)
assert_(sol.x.size < 110)
sol_test = sol.sol(x_test)
assert_allclose(sol_test[0], shock_sol(x_test), rtol=1e-5, atol=1e-5)
f_test = shock_fun(x_test, sol_test)
r = sol.sol(x_test, 1) - f_test
rel_res = r / (1 + np.abs(f_test))
norm_res = np.sum(rel_res ** 2, axis=0) ** 0.5
assert_(np.all(norm_res < 1e-3))
assert_allclose(sol.sol(sol.x), sol.y, rtol=1e-10, atol=1e-10)
assert_allclose(sol.sol(sol.x, 1), sol.yp, rtol=1e-10, atol=1e-10)
def test_nonlin_bc():
x = np.linspace(0, 0.1, 5)
x_test = x
y = np.zeros([2, x.size])
sol = solve_bvp(nonlin_bc_fun, nonlin_bc_bc, x, y)
assert_equal(sol.status, 0)
assert_(sol.success)
assert_(sol.x.size < 8)
sol_test = sol.sol(x_test)
assert_allclose(sol_test[0], nonlin_bc_sol(x_test), rtol=1e-5, atol=1e-5)
f_test = nonlin_bc_fun(x_test, sol_test)
r = sol.sol(x_test, 1) - f_test
rel_res = r / (1 + np.abs(f_test))
norm_res = np.sum(rel_res ** 2, axis=0) ** 0.5
assert_(np.all(norm_res < 1e-3))
assert_allclose(sol.sol(sol.x), sol.y, rtol=1e-10, atol=1e-10)
assert_allclose(sol.sol(sol.x, 1), sol.yp, rtol=1e-10, atol=1e-10)
def test_verbose():
# Smoke test that checks the printing does something and does not crash
x = np.linspace(0, 1, 5)
y = np.zeros((2, x.shape[0]))
for verbose in [0, 1, 2]:
old_stdout = sys.stdout
sys.stdout = StringIO()
try:
sol = solve_bvp(exp_fun, exp_bc, x, y, verbose=verbose)
text = sys.stdout.getvalue()
finally:
sys.stdout = old_stdout
assert_(sol.success)
if verbose == 0:
assert_(not text, text)
if verbose >= 1:
assert_("Solved in" in text, text)
if verbose >= 2:
assert_("Max residual" in text, text)

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# Authors: Nils Wagner, Ed Schofield, Pauli Virtanen, John Travers
"""
Tests for numerical integration.
"""
import numpy as np
from numpy import (arange, zeros, array, dot, sqrt, cos, sin, eye, pi, exp,
allclose)
from numpy.testing import (
assert_, assert_array_almost_equal,
assert_allclose, assert_array_equal, assert_equal, assert_warns)
from pytest import raises as assert_raises
from scipy.integrate import odeint, ode, complex_ode
#------------------------------------------------------------------------------
# Test ODE integrators
#------------------------------------------------------------------------------
class TestOdeint:
# Check integrate.odeint
def _do_problem(self, problem):
t = arange(0.0, problem.stop_t, 0.05)
# Basic case
z, infodict = odeint(problem.f, problem.z0, t, full_output=True)
assert_(problem.verify(z, t))
# Use tfirst=True
z, infodict = odeint(lambda t, y: problem.f(y, t), problem.z0, t,
full_output=True, tfirst=True)
assert_(problem.verify(z, t))
if hasattr(problem, 'jac'):
# Use Dfun
z, infodict = odeint(problem.f, problem.z0, t, Dfun=problem.jac,
full_output=True)
assert_(problem.verify(z, t))
# Use Dfun and tfirst=True
z, infodict = odeint(lambda t, y: problem.f(y, t), problem.z0, t,
Dfun=lambda t, y: problem.jac(y, t),
full_output=True, tfirst=True)
assert_(problem.verify(z, t))
def test_odeint(self):
for problem_cls in PROBLEMS:
problem = problem_cls()
if problem.cmplx:
continue
self._do_problem(problem)
class TestODEClass:
ode_class = None # Set in subclass.
def _do_problem(self, problem, integrator, method='adams'):
# ode has callback arguments in different order than odeint
f = lambda t, z: problem.f(z, t)
jac = None
if hasattr(problem, 'jac'):
jac = lambda t, z: problem.jac(z, t)
integrator_params = {}
if problem.lband is not None or problem.uband is not None:
integrator_params['uband'] = problem.uband
integrator_params['lband'] = problem.lband
ig = self.ode_class(f, jac)
ig.set_integrator(integrator,
atol=problem.atol/10,
rtol=problem.rtol/10,
method=method,
**integrator_params)
ig.set_initial_value(problem.z0, t=0.0)
z = ig.integrate(problem.stop_t)
assert_array_equal(z, ig.y)
assert_(ig.successful(), (problem, method))
assert_(ig.get_return_code() > 0, (problem, method))
assert_(problem.verify(array([z]), problem.stop_t), (problem, method))
class TestOde(TestODEClass):
ode_class = ode
def test_vode(self):
# Check the vode solver
for problem_cls in PROBLEMS:
problem = problem_cls()
if problem.cmplx:
continue
if not problem.stiff:
self._do_problem(problem, 'vode', 'adams')
self._do_problem(problem, 'vode', 'bdf')
def test_zvode(self):
# Check the zvode solver
for problem_cls in PROBLEMS:
problem = problem_cls()
if not problem.stiff:
self._do_problem(problem, 'zvode', 'adams')
self._do_problem(problem, 'zvode', 'bdf')
def test_lsoda(self):
# Check the lsoda solver
for problem_cls in PROBLEMS:
problem = problem_cls()
if problem.cmplx:
continue
self._do_problem(problem, 'lsoda')
def test_dopri5(self):
# Check the dopri5 solver
for problem_cls in PROBLEMS:
problem = problem_cls()
if problem.cmplx:
continue
if problem.stiff:
continue
if hasattr(problem, 'jac'):
continue
self._do_problem(problem, 'dopri5')
def test_dop853(self):
# Check the dop853 solver
for problem_cls in PROBLEMS:
problem = problem_cls()
if problem.cmplx:
continue
if problem.stiff:
continue
if hasattr(problem, 'jac'):
continue
self._do_problem(problem, 'dop853')
def test_concurrent_fail(self):
for sol in ('vode', 'zvode', 'lsoda'):
f = lambda t, y: 1.0
r = ode(f).set_integrator(sol)
r.set_initial_value(0, 0)
r2 = ode(f).set_integrator(sol)
r2.set_initial_value(0, 0)
r.integrate(r.t + 0.1)
r2.integrate(r2.t + 0.1)
assert_raises(RuntimeError, r.integrate, r.t + 0.1)
def test_concurrent_ok(self):
f = lambda t, y: 1.0
for k in range(3):
for sol in ('vode', 'zvode', 'lsoda', 'dopri5', 'dop853'):
r = ode(f).set_integrator(sol)
r.set_initial_value(0, 0)
r2 = ode(f).set_integrator(sol)
r2.set_initial_value(0, 0)
r.integrate(r.t + 0.1)
r2.integrate(r2.t + 0.1)
r2.integrate(r2.t + 0.1)
assert_allclose(r.y, 0.1)
assert_allclose(r2.y, 0.2)
for sol in ('dopri5', 'dop853'):
r = ode(f).set_integrator(sol)
r.set_initial_value(0, 0)
r2 = ode(f).set_integrator(sol)
r2.set_initial_value(0, 0)
r.integrate(r.t + 0.1)
r.integrate(r.t + 0.1)
r2.integrate(r2.t + 0.1)
r.integrate(r.t + 0.1)
r2.integrate(r2.t + 0.1)
assert_allclose(r.y, 0.3)
assert_allclose(r2.y, 0.2)
class TestComplexOde(TestODEClass):
ode_class = complex_ode
def test_vode(self):
# Check the vode solver
for problem_cls in PROBLEMS:
problem = problem_cls()
if not problem.stiff:
self._do_problem(problem, 'vode', 'adams')
else:
self._do_problem(problem, 'vode', 'bdf')
def test_lsoda(self):
# Check the lsoda solver
for problem_cls in PROBLEMS:
problem = problem_cls()
self._do_problem(problem, 'lsoda')
def test_dopri5(self):
# Check the dopri5 solver
for problem_cls in PROBLEMS:
problem = problem_cls()
if problem.stiff:
continue
if hasattr(problem, 'jac'):
continue
self._do_problem(problem, 'dopri5')
def test_dop853(self):
# Check the dop853 solver
for problem_cls in PROBLEMS:
problem = problem_cls()
if problem.stiff:
continue
if hasattr(problem, 'jac'):
continue
self._do_problem(problem, 'dop853')
class TestSolout:
# Check integrate.ode correctly handles solout for dopri5 and dop853
def _run_solout_test(self, integrator):
# Check correct usage of solout
ts = []
ys = []
t0 = 0.0
tend = 10.0
y0 = [1.0, 2.0]
def solout(t, y):
ts.append(t)
ys.append(y.copy())
def rhs(t, y):
return [y[0] + y[1], -y[1]**2]
ig = ode(rhs).set_integrator(integrator)
ig.set_solout(solout)
ig.set_initial_value(y0, t0)
ret = ig.integrate(tend)
assert_array_equal(ys[0], y0)
assert_array_equal(ys[-1], ret)
assert_equal(ts[0], t0)
assert_equal(ts[-1], tend)
def test_solout(self):
for integrator in ('dopri5', 'dop853'):
self._run_solout_test(integrator)
def _run_solout_after_initial_test(self, integrator):
# Check if solout works even if it is set after the initial value.
ts = []
ys = []
t0 = 0.0
tend = 10.0
y0 = [1.0, 2.0]
def solout(t, y):
ts.append(t)
ys.append(y.copy())
def rhs(t, y):
return [y[0] + y[1], -y[1]**2]
ig = ode(rhs).set_integrator(integrator)
ig.set_initial_value(y0, t0)
ig.set_solout(solout)
ret = ig.integrate(tend)
assert_array_equal(ys[0], y0)
assert_array_equal(ys[-1], ret)
assert_equal(ts[0], t0)
assert_equal(ts[-1], tend)
def test_solout_after_initial(self):
for integrator in ('dopri5', 'dop853'):
self._run_solout_after_initial_test(integrator)
def _run_solout_break_test(self, integrator):
# Check correct usage of stopping via solout
ts = []
ys = []
t0 = 0.0
tend = 10.0
y0 = [1.0, 2.0]
def solout(t, y):
ts.append(t)
ys.append(y.copy())
if t > tend/2.0:
return -1
def rhs(t, y):
return [y[0] + y[1], -y[1]**2]
ig = ode(rhs).set_integrator(integrator)
ig.set_solout(solout)
ig.set_initial_value(y0, t0)
ret = ig.integrate(tend)
assert_array_equal(ys[0], y0)
assert_array_equal(ys[-1], ret)
assert_equal(ts[0], t0)
assert_(ts[-1] > tend/2.0)
assert_(ts[-1] < tend)
def test_solout_break(self):
for integrator in ('dopri5', 'dop853'):
self._run_solout_break_test(integrator)
class TestComplexSolout:
# Check integrate.ode correctly handles solout for dopri5 and dop853
def _run_solout_test(self, integrator):
# Check correct usage of solout
ts = []
ys = []
t0 = 0.0
tend = 20.0
y0 = [0.0]
def solout(t, y):
ts.append(t)
ys.append(y.copy())
def rhs(t, y):
return [1.0/(t - 10.0 - 1j)]
ig = complex_ode(rhs).set_integrator(integrator)
ig.set_solout(solout)
ig.set_initial_value(y0, t0)
ret = ig.integrate(tend)
assert_array_equal(ys[0], y0)
assert_array_equal(ys[-1], ret)
assert_equal(ts[0], t0)
assert_equal(ts[-1], tend)
def test_solout(self):
for integrator in ('dopri5', 'dop853'):
self._run_solout_test(integrator)
def _run_solout_break_test(self, integrator):
# Check correct usage of stopping via solout
ts = []
ys = []
t0 = 0.0
tend = 20.0
y0 = [0.0]
def solout(t, y):
ts.append(t)
ys.append(y.copy())
if t > tend/2.0:
return -1
def rhs(t, y):
return [1.0/(t - 10.0 - 1j)]
ig = complex_ode(rhs).set_integrator(integrator)
ig.set_solout(solout)
ig.set_initial_value(y0, t0)
ret = ig.integrate(tend)
assert_array_equal(ys[0], y0)
assert_array_equal(ys[-1], ret)
assert_equal(ts[0], t0)
assert_(ts[-1] > tend/2.0)
assert_(ts[-1] < tend)
def test_solout_break(self):
for integrator in ('dopri5', 'dop853'):
self._run_solout_break_test(integrator)
#------------------------------------------------------------------------------
# Test problems
#------------------------------------------------------------------------------
class ODE:
"""
ODE problem
"""
stiff = False
cmplx = False
stop_t = 1
z0 = []
lband = None
uband = None
atol = 1e-6
rtol = 1e-5
class SimpleOscillator(ODE):
r"""
Free vibration of a simple oscillator::
m \ddot{u} + k u = 0, u(0) = u_0 \dot{u}(0) \dot{u}_0
Solution::
u(t) = u_0*cos(sqrt(k/m)*t)+\dot{u}_0*sin(sqrt(k/m)*t)/sqrt(k/m)
"""
stop_t = 1 + 0.09
z0 = array([1.0, 0.1], float)
k = 4.0
m = 1.0
def f(self, z, t):
tmp = zeros((2, 2), float)
tmp[0, 1] = 1.0
tmp[1, 0] = -self.k / self.m
return dot(tmp, z)
def verify(self, zs, t):
omega = sqrt(self.k / self.m)
u = self.z0[0]*cos(omega*t) + self.z0[1]*sin(omega*t)/omega
return allclose(u, zs[:, 0], atol=self.atol, rtol=self.rtol)
class ComplexExp(ODE):
r"""The equation :lm:`\dot u = i u`"""
stop_t = 1.23*pi
z0 = exp([1j, 2j, 3j, 4j, 5j])
cmplx = True
def f(self, z, t):
return 1j*z
def jac(self, z, t):
return 1j*eye(5)
def verify(self, zs, t):
u = self.z0 * exp(1j*t)
return allclose(u, zs, atol=self.atol, rtol=self.rtol)
class Pi(ODE):
r"""Integrate 1/(t + 1j) from t=-10 to t=10"""
stop_t = 20
z0 = [0]
cmplx = True
def f(self, z, t):
return array([1./(t - 10 + 1j)])
def verify(self, zs, t):
u = -2j * np.arctan(10)
return allclose(u, zs[-1, :], atol=self.atol, rtol=self.rtol)
class CoupledDecay(ODE):
r"""
3 coupled decays suited for banded treatment
(banded mode makes it necessary when N>>3)
"""
stiff = True
stop_t = 0.5
z0 = [5.0, 7.0, 13.0]
lband = 1
uband = 0
lmbd = [0.17, 0.23, 0.29] # fictitious decay constants
def f(self, z, t):
lmbd = self.lmbd
return np.array([-lmbd[0]*z[0],
-lmbd[1]*z[1] + lmbd[0]*z[0],
-lmbd[2]*z[2] + lmbd[1]*z[1]])
def jac(self, z, t):
# The full Jacobian is
#
# [-lmbd[0] 0 0 ]
# [ lmbd[0] -lmbd[1] 0 ]
# [ 0 lmbd[1] -lmbd[2]]
#
# The lower and upper bandwidths are lband=1 and uband=0, resp.
# The representation of this array in packed format is
#
# [-lmbd[0] -lmbd[1] -lmbd[2]]
# [ lmbd[0] lmbd[1] 0 ]
lmbd = self.lmbd
j = np.zeros((self.lband + self.uband + 1, 3), order='F')
def set_j(ri, ci, val):
j[self.uband + ri - ci, ci] = val
set_j(0, 0, -lmbd[0])
set_j(1, 0, lmbd[0])
set_j(1, 1, -lmbd[1])
set_j(2, 1, lmbd[1])
set_j(2, 2, -lmbd[2])
return j
def verify(self, zs, t):
# Formulae derived by hand
lmbd = np.array(self.lmbd)
d10 = lmbd[1] - lmbd[0]
d21 = lmbd[2] - lmbd[1]
d20 = lmbd[2] - lmbd[0]
e0 = np.exp(-lmbd[0] * t)
e1 = np.exp(-lmbd[1] * t)
e2 = np.exp(-lmbd[2] * t)
u = np.vstack((
self.z0[0] * e0,
self.z0[1] * e1 + self.z0[0] * lmbd[0] / d10 * (e0 - e1),
self.z0[2] * e2 + self.z0[1] * lmbd[1] / d21 * (e1 - e2) +
lmbd[1] * lmbd[0] * self.z0[0] / d10 *
(1 / d20 * (e0 - e2) - 1 / d21 * (e1 - e2)))).transpose()
return allclose(u, zs, atol=self.atol, rtol=self.rtol)
PROBLEMS = [SimpleOscillator, ComplexExp, Pi, CoupledDecay]
#------------------------------------------------------------------------------
def f(t, x):
dxdt = [x[1], -x[0]]
return dxdt
def jac(t, x):
j = array([[0.0, 1.0],
[-1.0, 0.0]])
return j
def f1(t, x, omega):
dxdt = [omega*x[1], -omega*x[0]]
return dxdt
def jac1(t, x, omega):
j = array([[0.0, omega],
[-omega, 0.0]])
return j
def f2(t, x, omega1, omega2):
dxdt = [omega1*x[1], -omega2*x[0]]
return dxdt
def jac2(t, x, omega1, omega2):
j = array([[0.0, omega1],
[-omega2, 0.0]])
return j
def fv(t, x, omega):
dxdt = [omega[0]*x[1], -omega[1]*x[0]]
return dxdt
def jacv(t, x, omega):
j = array([[0.0, omega[0]],
[-omega[1], 0.0]])
return j
class ODECheckParameterUse:
"""Call an ode-class solver with several cases of parameter use."""
# solver_name must be set before tests can be run with this class.
# Set these in subclasses.
solver_name = ''
solver_uses_jac = False
def _get_solver(self, f, jac):
solver = ode(f, jac)
if self.solver_uses_jac:
solver.set_integrator(self.solver_name, atol=1e-9, rtol=1e-7,
with_jacobian=self.solver_uses_jac)
else:
# XXX Shouldn't set_integrator *always* accept the keyword arg
# 'with_jacobian', and perhaps raise an exception if it is set
# to True if the solver can't actually use it?
solver.set_integrator(self.solver_name, atol=1e-9, rtol=1e-7)
return solver
def _check_solver(self, solver):
ic = [1.0, 0.0]
solver.set_initial_value(ic, 0.0)
solver.integrate(pi)
assert_array_almost_equal(solver.y, [-1.0, 0.0])
def test_no_params(self):
solver = self._get_solver(f, jac)
self._check_solver(solver)
def test_one_scalar_param(self):
solver = self._get_solver(f1, jac1)
omega = 1.0
solver.set_f_params(omega)
if self.solver_uses_jac:
solver.set_jac_params(omega)
self._check_solver(solver)
def test_two_scalar_params(self):
solver = self._get_solver(f2, jac2)
omega1 = 1.0
omega2 = 1.0
solver.set_f_params(omega1, omega2)
if self.solver_uses_jac:
solver.set_jac_params(omega1, omega2)
self._check_solver(solver)
def test_vector_param(self):
solver = self._get_solver(fv, jacv)
omega = [1.0, 1.0]
solver.set_f_params(omega)
if self.solver_uses_jac:
solver.set_jac_params(omega)
self._check_solver(solver)
def test_warns_on_failure(self):
# Set nsteps small to ensure failure
solver = self._get_solver(f, jac)
solver.set_integrator(self.solver_name, nsteps=1)
ic = [1.0, 0.0]
solver.set_initial_value(ic, 0.0)
assert_warns(UserWarning, solver.integrate, pi)
class TestDOPRI5CheckParameterUse(ODECheckParameterUse):
solver_name = 'dopri5'
solver_uses_jac = False
class TestDOP853CheckParameterUse(ODECheckParameterUse):
solver_name = 'dop853'
solver_uses_jac = False
class TestVODECheckParameterUse(ODECheckParameterUse):
solver_name = 'vode'
solver_uses_jac = True
class TestZVODECheckParameterUse(ODECheckParameterUse):
solver_name = 'zvode'
solver_uses_jac = True
class TestLSODACheckParameterUse(ODECheckParameterUse):
solver_name = 'lsoda'
solver_uses_jac = True
def test_odeint_trivial_time():
# Test that odeint succeeds when given a single time point
# and full_output=True. This is a regression test for gh-4282.
y0 = 1
t = [0]
y, info = odeint(lambda y, t: -y, y0, t, full_output=True)
assert_array_equal(y, np.array([[y0]]))
def test_odeint_banded_jacobian():
# Test the use of the `Dfun`, `ml` and `mu` options of odeint.
def func(y, t, c):
return c.dot(y)
def jac(y, t, c):
return c
def jac_transpose(y, t, c):
return c.T.copy(order='C')
def bjac_rows(y, t, c):
jac = np.row_stack((np.r_[0, np.diag(c, 1)],
np.diag(c),
np.r_[np.diag(c, -1), 0],
np.r_[np.diag(c, -2), 0, 0]))
return jac
def bjac_cols(y, t, c):
return bjac_rows(y, t, c).T.copy(order='C')
c = array([[-205, 0.01, 0.00, 0.0],
[0.1, -2.50, 0.02, 0.0],
[1e-3, 0.01, -2.0, 0.01],
[0.00, 0.00, 0.1, -1.0]])
y0 = np.ones(4)
t = np.array([0, 5, 10, 100])
# Use the full Jacobian.
sol1, info1 = odeint(func, y0, t, args=(c,), full_output=True,
atol=1e-13, rtol=1e-11, mxstep=10000,
Dfun=jac)
# Use the transposed full Jacobian, with col_deriv=True.
sol2, info2 = odeint(func, y0, t, args=(c,), full_output=True,
atol=1e-13, rtol=1e-11, mxstep=10000,
Dfun=jac_transpose, col_deriv=True)
# Use the banded Jacobian.
sol3, info3 = odeint(func, y0, t, args=(c,), full_output=True,
atol=1e-13, rtol=1e-11, mxstep=10000,
Dfun=bjac_rows, ml=2, mu=1)
# Use the transposed banded Jacobian, with col_deriv=True.
sol4, info4 = odeint(func, y0, t, args=(c,), full_output=True,
atol=1e-13, rtol=1e-11, mxstep=10000,
Dfun=bjac_cols, ml=2, mu=1, col_deriv=True)
assert_allclose(sol1, sol2, err_msg="sol1 != sol2")
assert_allclose(sol1, sol3, atol=1e-12, err_msg="sol1 != sol3")
assert_allclose(sol3, sol4, err_msg="sol3 != sol4")
# Verify that the number of jacobian evaluations was the same for the
# calls of odeint with a full jacobian and with a banded jacobian. This is
# a regression test--there was a bug in the handling of banded jacobians
# that resulted in an incorrect jacobian matrix being passed to the LSODA
# code. That would cause errors or excessive jacobian evaluations.
assert_array_equal(info1['nje'], info2['nje'])
assert_array_equal(info3['nje'], info4['nje'])
# Test the use of tfirst
sol1ty, info1ty = odeint(lambda t, y, c: func(y, t, c), y0, t, args=(c,),
full_output=True, atol=1e-13, rtol=1e-11,
mxstep=10000,
Dfun=lambda t, y, c: jac(y, t, c), tfirst=True)
# The code should execute the exact same sequence of floating point
# calculations, so these should be exactly equal. We'll be safe and use
# a small tolerance.
assert_allclose(sol1, sol1ty, rtol=1e-12, err_msg="sol1 != sol1ty")
def test_odeint_errors():
def sys1d(x, t):
return -100*x
def bad1(x, t):
return 1.0/0
def bad2(x, t):
return "foo"
def bad_jac1(x, t):
return 1.0/0
def bad_jac2(x, t):
return [["foo"]]
def sys2d(x, t):
return [-100*x[0], -0.1*x[1]]
def sys2d_bad_jac(x, t):
return [[1.0/0, 0], [0, -0.1]]
assert_raises(ZeroDivisionError, odeint, bad1, 1.0, [0, 1])
assert_raises(ValueError, odeint, bad2, 1.0, [0, 1])
assert_raises(ZeroDivisionError, odeint, sys1d, 1.0, [0, 1], Dfun=bad_jac1)
assert_raises(ValueError, odeint, sys1d, 1.0, [0, 1], Dfun=bad_jac2)
assert_raises(ZeroDivisionError, odeint, sys2d, [1.0, 1.0], [0, 1],
Dfun=sys2d_bad_jac)
def test_odeint_bad_shapes():
# Tests of some errors that can occur with odeint.
def badrhs(x, t):
return [1, -1]
def sys1(x, t):
return -100*x
def badjac(x, t):
return [[0, 0, 0]]
# y0 must be at most 1-d.
bad_y0 = [[0, 0], [0, 0]]
assert_raises(ValueError, odeint, sys1, bad_y0, [0, 1])
# t must be at most 1-d.
bad_t = [[0, 1], [2, 3]]
assert_raises(ValueError, odeint, sys1, [10.0], bad_t)
# y0 is 10, but badrhs(x, t) returns [1, -1].
assert_raises(RuntimeError, odeint, badrhs, 10, [0, 1])
# shape of array returned by badjac(x, t) is not correct.
assert_raises(RuntimeError, odeint, sys1, [10, 10], [0, 1], Dfun=badjac)
def test_repeated_t_values():
"""Regression test for gh-8217."""
def func(x, t):
return -0.25*x
t = np.zeros(10)
sol = odeint(func, [1.], t)
assert_array_equal(sol, np.ones((len(t), 1)))
tau = 4*np.log(2)
t = [0]*9 + [tau, 2*tau, 2*tau, 3*tau]
sol = odeint(func, [1, 2], t, rtol=1e-12, atol=1e-12)
expected_sol = np.array([[1.0, 2.0]]*9 +
[[0.5, 1.0],
[0.25, 0.5],
[0.25, 0.5],
[0.125, 0.25]])
assert_allclose(sol, expected_sol)
# Edge case: empty t sequence.
sol = odeint(func, [1.], [])
assert_array_equal(sol, np.array([], dtype=np.float64).reshape((0, 1)))
# t values are not monotonic.
assert_raises(ValueError, odeint, func, [1.], [0, 1, 0.5, 0])
assert_raises(ValueError, odeint, func, [1, 2, 3], [0, -1, -2, 3])

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import numpy as np
from numpy.testing import assert_equal, assert_allclose
from scipy.integrate import odeint
import scipy.integrate._test_odeint_banded as banded5x5
def rhs(y, t):
dydt = np.zeros_like(y)
banded5x5.banded5x5(t, y, dydt)
return dydt
def jac(y, t):
n = len(y)
jac = np.zeros((n, n), order='F')
banded5x5.banded5x5_jac(t, y, 1, 1, jac)
return jac
def bjac(y, t):
n = len(y)
bjac = np.zeros((4, n), order='F')
banded5x5.banded5x5_bjac(t, y, 1, 1, bjac)
return bjac
JACTYPE_FULL = 1
JACTYPE_BANDED = 4
def check_odeint(jactype):
if jactype == JACTYPE_FULL:
ml = None
mu = None
jacobian = jac
elif jactype == JACTYPE_BANDED:
ml = 2
mu = 1
jacobian = bjac
else:
raise ValueError("invalid jactype: %r" % (jactype,))
y0 = np.arange(1.0, 6.0)
# These tolerances must match the tolerances used in banded5x5.f.
rtol = 1e-11
atol = 1e-13
dt = 0.125
nsteps = 64
t = dt * np.arange(nsteps+1)
sol, info = odeint(rhs, y0, t,
Dfun=jacobian, ml=ml, mu=mu,
atol=atol, rtol=rtol, full_output=True)
yfinal = sol[-1]
odeint_nst = info['nst'][-1]
odeint_nfe = info['nfe'][-1]
odeint_nje = info['nje'][-1]
y1 = y0.copy()
# Pure Fortran solution. y1 is modified in-place.
nst, nfe, nje = banded5x5.banded5x5_solve(y1, nsteps, dt, jactype)
# It is likely that yfinal and y1 are *exactly* the same, but
# we'll be cautious and use assert_allclose.
assert_allclose(yfinal, y1, rtol=1e-12)
assert_equal((odeint_nst, odeint_nfe, odeint_nje), (nst, nfe, nje))
def test_odeint_full_jac():
check_odeint(JACTYPE_FULL)
def test_odeint_banded_jac():
check_odeint(JACTYPE_BANDED)

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import sys
import math
import numpy as np
from numpy import sqrt, cos, sin, arctan, exp, log, pi, Inf
from numpy.testing import (assert_,
assert_allclose, assert_array_less, assert_almost_equal)
import pytest
from scipy.integrate import quad, dblquad, tplquad, nquad
from scipy.special import erf, erfc
from scipy._lib._ccallback import LowLevelCallable
import ctypes
import ctypes.util
from scipy._lib._ccallback_c import sine_ctypes
import scipy.integrate._test_multivariate as clib_test
def assert_quad(value_and_err, tabled_value, error_tolerance=1.5e-8):
value, err = value_and_err
assert_allclose(value, tabled_value, atol=err, rtol=0)
if error_tolerance is not None:
assert_array_less(err, error_tolerance)
def get_clib_test_routine(name, restype, *argtypes):
ptr = getattr(clib_test, name)
return ctypes.cast(ptr, ctypes.CFUNCTYPE(restype, *argtypes))
class TestCtypesQuad:
def setup_method(self):
if sys.platform == 'win32':
files = ['api-ms-win-crt-math-l1-1-0.dll']
elif sys.platform == 'darwin':
files = ['libm.dylib']
else:
files = ['libm.so', 'libm.so.6']
for file in files:
try:
self.lib = ctypes.CDLL(file)
break
except OSError:
pass
else:
# This test doesn't work on some Linux platforms (Fedora for
# example) that put an ld script in libm.so - see gh-5370
pytest.skip("Ctypes can't import libm.so")
restype = ctypes.c_double
argtypes = (ctypes.c_double,)
for name in ['sin', 'cos', 'tan']:
func = getattr(self.lib, name)
func.restype = restype
func.argtypes = argtypes
def test_typical(self):
assert_quad(quad(self.lib.sin, 0, 5), quad(math.sin, 0, 5)[0])
assert_quad(quad(self.lib.cos, 0, 5), quad(math.cos, 0, 5)[0])
assert_quad(quad(self.lib.tan, 0, 1), quad(math.tan, 0, 1)[0])
def test_ctypes_sine(self):
quad(LowLevelCallable(sine_ctypes), 0, 1)
def test_ctypes_variants(self):
sin_0 = get_clib_test_routine('_sin_0', ctypes.c_double,
ctypes.c_double, ctypes.c_void_p)
sin_1 = get_clib_test_routine('_sin_1', ctypes.c_double,
ctypes.c_int, ctypes.POINTER(ctypes.c_double),
ctypes.c_void_p)
sin_2 = get_clib_test_routine('_sin_2', ctypes.c_double,
ctypes.c_double)
sin_3 = get_clib_test_routine('_sin_3', ctypes.c_double,
ctypes.c_int, ctypes.POINTER(ctypes.c_double))
sin_4 = get_clib_test_routine('_sin_3', ctypes.c_double,
ctypes.c_int, ctypes.c_double)
all_sigs = [sin_0, sin_1, sin_2, sin_3, sin_4]
legacy_sigs = [sin_2, sin_4]
legacy_only_sigs = [sin_4]
# LowLevelCallables work for new signatures
for j, func in enumerate(all_sigs):
callback = LowLevelCallable(func)
if func in legacy_only_sigs:
pytest.raises(ValueError, quad, callback, 0, pi)
else:
assert_allclose(quad(callback, 0, pi)[0], 2.0)
# Plain ctypes items work only for legacy signatures
for j, func in enumerate(legacy_sigs):
if func in legacy_sigs:
assert_allclose(quad(func, 0, pi)[0], 2.0)
else:
pytest.raises(ValueError, quad, func, 0, pi)
class TestMultivariateCtypesQuad:
def setup_method(self):
restype = ctypes.c_double
argtypes = (ctypes.c_int, ctypes.c_double)
for name in ['_multivariate_typical', '_multivariate_indefinite',
'_multivariate_sin']:
func = get_clib_test_routine(name, restype, *argtypes)
setattr(self, name, func)
def test_typical(self):
# 1) Typical function with two extra arguments:
assert_quad(quad(self._multivariate_typical, 0, pi, (2, 1.8)),
0.30614353532540296487)
def test_indefinite(self):
# 2) Infinite integration limits --- Euler's constant
assert_quad(quad(self._multivariate_indefinite, 0, Inf),
0.577215664901532860606512)
def test_threadsafety(self):
# Ensure multivariate ctypes are threadsafe
def threadsafety(y):
return y + quad(self._multivariate_sin, 0, 1)[0]
assert_quad(quad(threadsafety, 0, 1), 0.9596976941318602)
class TestQuad:
def test_typical(self):
# 1) Typical function with two extra arguments:
def myfunc(x, n, z): # Bessel function integrand
return cos(n*x-z*sin(x))/pi
assert_quad(quad(myfunc, 0, pi, (2, 1.8)), 0.30614353532540296487)
def test_indefinite(self):
# 2) Infinite integration limits --- Euler's constant
def myfunc(x): # Euler's constant integrand
return -exp(-x)*log(x)
assert_quad(quad(myfunc, 0, Inf), 0.577215664901532860606512)
def test_singular(self):
# 3) Singular points in region of integration.
def myfunc(x):
if 0 < x < 2.5:
return sin(x)
elif 2.5 <= x <= 5.0:
return exp(-x)
else:
return 0.0
assert_quad(quad(myfunc, 0, 10, points=[2.5, 5.0]),
1 - cos(2.5) + exp(-2.5) - exp(-5.0))
def test_sine_weighted_finite(self):
# 4) Sine weighted integral (finite limits)
def myfunc(x, a):
return exp(a*(x-1))
ome = 2.0**3.4
assert_quad(quad(myfunc, 0, 1, args=20, weight='sin', wvar=ome),
(20*sin(ome)-ome*cos(ome)+ome*exp(-20))/(20**2 + ome**2))
def test_sine_weighted_infinite(self):
# 5) Sine weighted integral (infinite limits)
def myfunc(x, a):
return exp(-x*a)
a = 4.0
ome = 3.0
assert_quad(quad(myfunc, 0, Inf, args=a, weight='sin', wvar=ome),
ome/(a**2 + ome**2))
def test_cosine_weighted_infinite(self):
# 6) Cosine weighted integral (negative infinite limits)
def myfunc(x, a):
return exp(x*a)
a = 2.5
ome = 2.3
assert_quad(quad(myfunc, -Inf, 0, args=a, weight='cos', wvar=ome),
a/(a**2 + ome**2))
def test_algebraic_log_weight(self):
# 6) Algebraic-logarithmic weight.
def myfunc(x, a):
return 1/(1+x+2**(-a))
a = 1.5
assert_quad(quad(myfunc, -1, 1, args=a, weight='alg',
wvar=(-0.5, -0.5)),
pi/sqrt((1+2**(-a))**2 - 1))
def test_cauchypv_weight(self):
# 7) Cauchy prinicpal value weighting w(x) = 1/(x-c)
def myfunc(x, a):
return 2.0**(-a)/((x-1)**2+4.0**(-a))
a = 0.4
tabledValue = ((2.0**(-0.4)*log(1.5) -
2.0**(-1.4)*log((4.0**(-a)+16) / (4.0**(-a)+1)) -
arctan(2.0**(a+2)) -
arctan(2.0**a)) /
(4.0**(-a) + 1))
assert_quad(quad(myfunc, 0, 5, args=0.4, weight='cauchy', wvar=2.0),
tabledValue, error_tolerance=1.9e-8)
def test_b_less_than_a(self):
def f(x, p, q):
return p * np.exp(-q*x)
val_1, err_1 = quad(f, 0, np.inf, args=(2, 3))
val_2, err_2 = quad(f, np.inf, 0, args=(2, 3))
assert_allclose(val_1, -val_2, atol=max(err_1, err_2))
def test_b_less_than_a_2(self):
def f(x, s):
return np.exp(-x**2 / 2 / s) / np.sqrt(2.*s)
val_1, err_1 = quad(f, -np.inf, np.inf, args=(2,))
val_2, err_2 = quad(f, np.inf, -np.inf, args=(2,))
assert_allclose(val_1, -val_2, atol=max(err_1, err_2))
def test_b_less_than_a_3(self):
def f(x):
return 1.0
val_1, err_1 = quad(f, 0, 1, weight='alg', wvar=(0, 0))
val_2, err_2 = quad(f, 1, 0, weight='alg', wvar=(0, 0))
assert_allclose(val_1, -val_2, atol=max(err_1, err_2))
def test_b_less_than_a_full_output(self):
def f(x):
return 1.0
res_1 = quad(f, 0, 1, weight='alg', wvar=(0, 0), full_output=True)
res_2 = quad(f, 1, 0, weight='alg', wvar=(0, 0), full_output=True)
err = max(res_1[1], res_2[1])
assert_allclose(res_1[0], -res_2[0], atol=err)
def test_double_integral(self):
# 8) Double Integral test
def simpfunc(y, x): # Note order of arguments.
return x+y
a, b = 1.0, 2.0
assert_quad(dblquad(simpfunc, a, b, lambda x: x, lambda x: 2*x),
5/6.0 * (b**3.0-a**3.0))
def test_double_integral2(self):
def func(x0, x1, t0, t1):
return x0 + x1 + t0 + t1
g = lambda x: x
h = lambda x: 2 * x
args = 1, 2
assert_quad(dblquad(func, 1, 2, g, h, args=args),35./6 + 9*.5)
def test_double_integral3(self):
def func(x0, x1):
return x0 + x1 + 1 + 2
assert_quad(dblquad(func, 1, 2, 1, 2),6.)
@pytest.mark.parametrize(
"x_lower, x_upper, y_lower, y_upper, expected",
[
# Multiple integration of a function in n = 2 variables: f(x, y, z)
# over domain D = [-inf, 0] for all n.
(-np.inf, 0, -np.inf, 0, np.pi / 4),
# Multiple integration of a function in n = 2 variables: f(x, y, z)
# over domain D = [-inf, -1] for each n (one at a time).
(-np.inf, -1, -np.inf, 0, np.pi / 4 * erfc(1)),
(-np.inf, 0, -np.inf, -1, np.pi / 4 * erfc(1)),
# Multiple integration of a function in n = 2 variables: f(x, y, z)
# over domain D = [-inf, -1] for all n.
(-np.inf, -1, -np.inf, -1, np.pi / 4 * (erfc(1) ** 2)),
# Multiple integration of a function in n = 2 variables: f(x, y, z)
# over domain D = [-inf, 1] for each n (one at a time).
(-np.inf, 1, -np.inf, 0, np.pi / 4 * (erf(1) + 1)),
(-np.inf, 0, -np.inf, 1, np.pi / 4 * (erf(1) + 1)),
# Multiple integration of a function in n = 2 variables: f(x, y, z)
# over domain D = [-inf, 1] for all n.
(-np.inf, 1, -np.inf, 1, np.pi / 4 * ((erf(1) + 1) ** 2)),
# Multiple integration of a function in n = 2 variables: f(x, y, z)
# over domain Dx = [-inf, -1] and Dy = [-inf, 1].
(-np.inf, -1, -np.inf, 1, np.pi / 4 * ((erf(1) + 1) * erfc(1))),
# Multiple integration of a function in n = 2 variables: f(x, y, z)
# over domain Dx = [-inf, 1] and Dy = [-inf, -1].
(-np.inf, 1, -np.inf, -1, np.pi / 4 * ((erf(1) + 1) * erfc(1))),
# Multiple integration of a function in n = 2 variables: f(x, y, z)
# over domain D = [0, inf] for all n.
(0, np.inf, 0, np.inf, np.pi / 4),
# Multiple integration of a function in n = 2 variables: f(x, y, z)
# over domain D = [1, inf] for each n (one at a time).
(1, np.inf, 0, np.inf, np.pi / 4 * erfc(1)),
(0, np.inf, 1, np.inf, np.pi / 4 * erfc(1)),
# Multiple integration of a function in n = 2 variables: f(x, y, z)
# over domain D = [1, inf] for all n.
(1, np.inf, 1, np.inf, np.pi / 4 * (erfc(1) ** 2)),
# Multiple integration of a function in n = 2 variables: f(x, y, z)
# over domain D = [-1, inf] for each n (one at a time).
(-1, np.inf, 0, np.inf, np.pi / 4 * (erf(1) + 1)),
(0, np.inf, -1, np.inf, np.pi / 4 * (erf(1) + 1)),
# Multiple integration of a function in n = 2 variables: f(x, y, z)
# over domain D = [-1, inf] for all n.
(-1, np.inf, -1, np.inf, np.pi / 4 * ((erf(1) + 1) ** 2)),
# Multiple integration of a function in n = 2 variables: f(x, y, z)
# over domain Dx = [-1, inf] and Dy = [1, inf].
(-1, np.inf, 1, np.inf, np.pi / 4 * ((erf(1) + 1) * erfc(1))),
# Multiple integration of a function in n = 2 variables: f(x, y, z)
# over domain Dx = [1, inf] and Dy = [-1, inf].
(1, np.inf, -1, np.inf, np.pi / 4 * ((erf(1) + 1) * erfc(1))),
# Multiple integration of a function in n = 2 variables: f(x, y, z)
# over domain D = [-inf, inf] for all n.
(-np.inf, np.inf, -np.inf, np.inf, np.pi)
]
)
def test_double_integral_improper(
self, x_lower, x_upper, y_lower, y_upper, expected
):
# The Gaussian Integral.
def f(x, y):
return np.exp(-x ** 2 - y ** 2)
assert_quad(
dblquad(f, x_lower, x_upper, y_lower, y_upper),
expected,
error_tolerance=3e-8
)
def test_triple_integral(self):
# 9) Triple Integral test
def simpfunc(z, y, x, t): # Note order of arguments.
return (x+y+z)*t
a, b = 1.0, 2.0
assert_quad(tplquad(simpfunc, a, b,
lambda x: x, lambda x: 2*x,
lambda x, y: x - y, lambda x, y: x + y,
(2.,)),
2*8/3.0 * (b**4.0 - a**4.0))
@pytest.mark.parametrize(
"x_lower, x_upper, y_lower, y_upper, z_lower, z_upper, expected",
[
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain D = [-inf, 0] for all n.
(-np.inf, 0, -np.inf, 0, -np.inf, 0, (np.pi ** (3 / 2)) / 8),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain D = [-inf, -1] for each n (one at a time).
(-np.inf, -1, -np.inf, 0, -np.inf, 0,
(np.pi ** (3 / 2)) / 8 * erfc(1)),
(-np.inf, 0, -np.inf, -1, -np.inf, 0,
(np.pi ** (3 / 2)) / 8 * erfc(1)),
(-np.inf, 0, -np.inf, 0, -np.inf, -1,
(np.pi ** (3 / 2)) / 8 * erfc(1)),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain D = [-inf, -1] for each n (two at a time).
(-np.inf, -1, -np.inf, -1, -np.inf, 0,
(np.pi ** (3 / 2)) / 8 * (erfc(1) ** 2)),
(-np.inf, -1, -np.inf, 0, -np.inf, -1,
(np.pi ** (3 / 2)) / 8 * (erfc(1) ** 2)),
(-np.inf, 0, -np.inf, -1, -np.inf, -1,
(np.pi ** (3 / 2)) / 8 * (erfc(1) ** 2)),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain D = [-inf, -1] for all n.
(-np.inf, -1, -np.inf, -1, -np.inf, -1,
(np.pi ** (3 / 2)) / 8 * (erfc(1) ** 3)),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain Dx = [-inf, -1] and Dy = Dz = [-inf, 1].
(-np.inf, -1, -np.inf, 1, -np.inf, 1,
(np.pi ** (3 / 2)) / 8 * (((erf(1) + 1) ** 2) * erfc(1))),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain Dx = Dy = [-inf, -1] and Dz = [-inf, 1].
(-np.inf, -1, -np.inf, -1, -np.inf, 1,
(np.pi ** (3 / 2)) / 8 * ((erf(1) + 1) * (erfc(1) ** 2))),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain Dx = Dz = [-inf, -1] and Dy = [-inf, 1].
(-np.inf, -1, -np.inf, 1, -np.inf, -1,
(np.pi ** (3 / 2)) / 8 * ((erf(1) + 1) * (erfc(1) ** 2))),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain Dx = [-inf, 1] and Dy = Dz = [-inf, -1].
(-np.inf, 1, -np.inf, -1, -np.inf, -1,
(np.pi ** (3 / 2)) / 8 * ((erf(1) + 1) * (erfc(1) ** 2))),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain Dx = Dy = [-inf, 1] and Dz = [-inf, -1].
(-np.inf, 1, -np.inf, 1, -np.inf, -1,
(np.pi ** (3 / 2)) / 8 * (((erf(1) + 1) ** 2) * erfc(1))),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain Dx = Dz = [-inf, 1] and Dy = [-inf, -1].
(-np.inf, 1, -np.inf, -1, -np.inf, 1,
(np.pi ** (3 / 2)) / 8 * (((erf(1) + 1) ** 2) * erfc(1))),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain D = [-inf, 1] for each n (one at a time).
(-np.inf, 1, -np.inf, 0, -np.inf, 0,
(np.pi ** (3 / 2)) / 8 * (erf(1) + 1)),
(-np.inf, 0, -np.inf, 1, -np.inf, 0,
(np.pi ** (3 / 2)) / 8 * (erf(1) + 1)),
(-np.inf, 0, -np.inf, 0, -np.inf, 1,
(np.pi ** (3 / 2)) / 8 * (erf(1) + 1)),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain D = [-inf, 1] for each n (two at a time).
(-np.inf, 1, -np.inf, 1, -np.inf, 0,
(np.pi ** (3 / 2)) / 8 * ((erf(1) + 1) ** 2)),
(-np.inf, 1, -np.inf, 0, -np.inf, 1,
(np.pi ** (3 / 2)) / 8 * ((erf(1) + 1) ** 2)),
(-np.inf, 0, -np.inf, 1, -np.inf, 1,
(np.pi ** (3 / 2)) / 8 * ((erf(1) + 1) ** 2)),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain D = [-inf, 1] for all n.
(-np.inf, 1, -np.inf, 1, -np.inf, 1,
(np.pi ** (3 / 2)) / 8 * ((erf(1) + 1) ** 3)),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain D = [0, inf] for all n.
(0, np.inf, 0, np.inf, 0, np.inf, (np.pi ** (3 / 2)) / 8),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain D = [1, inf] for each n (one at a time).
(1, np.inf, 0, np.inf, 0, np.inf,
(np.pi ** (3 / 2)) / 8 * erfc(1)),
(0, np.inf, 1, np.inf, 0, np.inf,
(np.pi ** (3 / 2)) / 8 * erfc(1)),
(0, np.inf, 0, np.inf, 1, np.inf,
(np.pi ** (3 / 2)) / 8 * erfc(1)),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain D = [1, inf] for each n (two at a time).
(1, np.inf, 1, np.inf, 0, np.inf,
(np.pi ** (3 / 2)) / 8 * (erfc(1) ** 2)),
(1, np.inf, 0, np.inf, 1, np.inf,
(np.pi ** (3 / 2)) / 8 * (erfc(1) ** 2)),
(0, np.inf, 1, np.inf, 1, np.inf,
(np.pi ** (3 / 2)) / 8 * (erfc(1) ** 2)),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain D = [1, inf] for all n.
(1, np.inf, 1, np.inf, 1, np.inf,
(np.pi ** (3 / 2)) / 8 * (erfc(1) ** 3)),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain D = [-1, inf] for each n (one at a time).
(-1, np.inf, 0, np.inf, 0, np.inf,
(np.pi ** (3 / 2)) / 8 * (erf(1) + 1)),
(0, np.inf, -1, np.inf, 0, np.inf,
(np.pi ** (3 / 2)) / 8 * (erf(1) + 1)),
(0, np.inf, 0, np.inf, -1, np.inf,
(np.pi ** (3 / 2)) / 8 * (erf(1) + 1)),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain D = [-1, inf] for each n (two at a time).
(-1, np.inf, -1, np.inf, 0, np.inf,
(np.pi ** (3 / 2)) / 8 * ((erf(1) + 1) ** 2)),
(-1, np.inf, 0, np.inf, -1, np.inf,
(np.pi ** (3 / 2)) / 8 * ((erf(1) + 1) ** 2)),
(0, np.inf, -1, np.inf, -1, np.inf,
(np.pi ** (3 / 2)) / 8 * ((erf(1) + 1) ** 2)),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain D = [-1, inf] for all n.
(-1, np.inf, -1, np.inf, -1, np.inf,
(np.pi ** (3 / 2)) / 8 * ((erf(1) + 1) ** 3)),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain Dx = [1, inf] and Dy = Dz = [-1, inf].
(1, np.inf, -1, np.inf, -1, np.inf,
(np.pi ** (3 / 2)) / 8 * (((erf(1) + 1) ** 2) * erfc(1))),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain Dx = Dy = [1, inf] and Dz = [-1, inf].
(1, np.inf, 1, np.inf, -1, np.inf,
(np.pi ** (3 / 2)) / 8 * ((erf(1) + 1) * (erfc(1) ** 2))),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain Dx = Dz = [1, inf] and Dy = [-1, inf].
(1, np.inf, -1, np.inf, 1, np.inf,
(np.pi ** (3 / 2)) / 8 * ((erf(1) + 1) * (erfc(1) ** 2))),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain Dx = [-1, inf] and Dy = Dz = [1, inf].
(-1, np.inf, 1, np.inf, 1, np.inf,
(np.pi ** (3 / 2)) / 8 * ((erf(1) + 1) * (erfc(1) ** 2))),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain Dx = Dy = [-1, inf] and Dz = [1, inf].
(-1, np.inf, -1, np.inf, 1, np.inf,
(np.pi ** (3 / 2)) / 8 * (((erf(1) + 1) ** 2) * erfc(1))),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain Dx = Dz = [-1, inf] and Dy = [1, inf].
(-1, np.inf, 1, np.inf, -1, np.inf,
(np.pi ** (3 / 2)) / 8 * (((erf(1) + 1) ** 2) * erfc(1))),
# Multiple integration of a function in n = 3 variables: f(x, y, z)
# over domain D = [-inf, inf] for all n.
(-np.inf, np.inf, -np.inf, np.inf, -np.inf, np.inf,
np.pi ** (3 / 2)),
],
)
def test_triple_integral_improper(
self,
x_lower,
x_upper,
y_lower,
y_upper,
z_lower,
z_upper,
expected
):
# The Gaussian Integral.
def f(x, y, z):
return np.exp(-x ** 2 - y ** 2 - z ** 2)
assert_quad(
tplquad(f, x_lower, x_upper, y_lower, y_upper, z_lower, z_upper),
expected,
error_tolerance=6e-8
)
def test_complex(self):
def tfunc(x):
return np.exp(1j*x)
assert np.allclose(
quad(tfunc, 0, np.pi/2, complex_func=True)[0],
1+1j)
# We consider a divergent case in order to force quadpack
# to return an error message. The output is compared
# against what is returned by explicit integration
# of the parts.
kwargs = {'a': 0, 'b': np.inf, 'full_output': True,
'weight': 'cos', 'wvar': 1}
res_c = quad(tfunc, complex_func=True, **kwargs)
res_r = quad(lambda x: np.real(np.exp(1j*x)),
complex_func=False,
**kwargs)
res_i = quad(lambda x: np.imag(np.exp(1j*x)),
complex_func=False,
**kwargs)
np.testing.assert_equal(res_c[0], res_r[0] + 1j*res_i[0])
np.testing.assert_equal(res_c[1], res_r[1] + 1j*res_i[1])
assert len(res_c[2]['real']) == len(res_r[2:]) == 3
assert res_c[2]['real'][2] == res_r[4]
assert res_c[2]['real'][1] == res_r[3]
assert res_c[2]['real'][0]['lst'] == res_r[2]['lst']
assert len(res_c[2]['imag']) == len(res_i[2:]) == 1
assert res_c[2]['imag'][0]['lst'] == res_i[2]['lst']
class TestNQuad:
def test_fixed_limits(self):
def func1(x0, x1, x2, x3):
val = (x0**2 + x1*x2 - x3**3 + np.sin(x0) +
(1 if (x0 - 0.2*x3 - 0.5 - 0.25*x1 > 0) else 0))
return val
def opts_basic(*args):
return {'points': [0.2*args[2] + 0.5 + 0.25*args[0]]}
res = nquad(func1, [[0, 1], [-1, 1], [.13, .8], [-.15, 1]],
opts=[opts_basic, {}, {}, {}], full_output=True)
assert_quad(res[:-1], 1.5267454070738635)
assert_(res[-1]['neval'] > 0 and res[-1]['neval'] < 4e5)
def test_variable_limits(self):
scale = .1
def func2(x0, x1, x2, x3, t0, t1):
val = (x0*x1*x3**2 + np.sin(x2) + 1 +
(1 if x0 + t1*x1 - t0 > 0 else 0))
return val
def lim0(x1, x2, x3, t0, t1):
return [scale * (x1**2 + x2 + np.cos(x3)*t0*t1 + 1) - 1,
scale * (x1**2 + x2 + np.cos(x3)*t0*t1 + 1) + 1]
def lim1(x2, x3, t0, t1):
return [scale * (t0*x2 + t1*x3) - 1,
scale * (t0*x2 + t1*x3) + 1]
def lim2(x3, t0, t1):
return [scale * (x3 + t0**2*t1**3) - 1,
scale * (x3 + t0**2*t1**3) + 1]
def lim3(t0, t1):
return [scale * (t0 + t1) - 1, scale * (t0 + t1) + 1]
def opts0(x1, x2, x3, t0, t1):
return {'points': [t0 - t1*x1]}
def opts1(x2, x3, t0, t1):
return {}
def opts2(x3, t0, t1):
return {}
def opts3(t0, t1):
return {}
res = nquad(func2, [lim0, lim1, lim2, lim3], args=(0, 0),
opts=[opts0, opts1, opts2, opts3])
assert_quad(res, 25.066666666666663)
def test_square_separate_ranges_and_opts(self):
def f(y, x):
return 1.0
assert_quad(nquad(f, [[-1, 1], [-1, 1]], opts=[{}, {}]), 4.0)
def test_square_aliased_ranges_and_opts(self):
def f(y, x):
return 1.0
r = [-1, 1]
opt = {}
assert_quad(nquad(f, [r, r], opts=[opt, opt]), 4.0)
def test_square_separate_fn_ranges_and_opts(self):
def f(y, x):
return 1.0
def fn_range0(*args):
return (-1, 1)
def fn_range1(*args):
return (-1, 1)
def fn_opt0(*args):
return {}
def fn_opt1(*args):
return {}
ranges = [fn_range0, fn_range1]
opts = [fn_opt0, fn_opt1]
assert_quad(nquad(f, ranges, opts=opts), 4.0)
def test_square_aliased_fn_ranges_and_opts(self):
def f(y, x):
return 1.0
def fn_range(*args):
return (-1, 1)
def fn_opt(*args):
return {}
ranges = [fn_range, fn_range]
opts = [fn_opt, fn_opt]
assert_quad(nquad(f, ranges, opts=opts), 4.0)
def test_matching_quad(self):
def func(x):
return x**2 + 1
res, reserr = quad(func, 0, 4)
res2, reserr2 = nquad(func, ranges=[[0, 4]])
assert_almost_equal(res, res2)
assert_almost_equal(reserr, reserr2)
def test_matching_dblquad(self):
def func2d(x0, x1):
return x0**2 + x1**3 - x0 * x1 + 1
res, reserr = dblquad(func2d, -2, 2, lambda x: -3, lambda x: 3)
res2, reserr2 = nquad(func2d, [[-3, 3], (-2, 2)])
assert_almost_equal(res, res2)
assert_almost_equal(reserr, reserr2)
def test_matching_tplquad(self):
def func3d(x0, x1, x2, c0, c1):
return x0**2 + c0 * x1**3 - x0 * x1 + 1 + c1 * np.sin(x2)
res = tplquad(func3d, -1, 2, lambda x: -2, lambda x: 2,
lambda x, y: -np.pi, lambda x, y: np.pi,
args=(2, 3))
res2 = nquad(func3d, [[-np.pi, np.pi], [-2, 2], (-1, 2)], args=(2, 3))
assert_almost_equal(res, res2)
def test_dict_as_opts(self):
try:
nquad(lambda x, y: x * y, [[0, 1], [0, 1]], opts={'epsrel': 0.0001})
except TypeError:
assert False

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import pytest
import numpy as np
from numpy import cos, sin, pi
from numpy.testing import (assert_equal, assert_almost_equal, assert_allclose,
assert_, suppress_warnings)
from scipy.integrate import (quadrature, romberg, romb, newton_cotes,
cumulative_trapezoid, cumtrapz, trapz, trapezoid,
quad, simpson, simps, fixed_quad, AccuracyWarning)
from scipy.integrate._quadrature import _qmc_quad as qmc_quad
from scipy import stats, special as sc
class TestFixedQuad:
def test_scalar(self):
n = 4
expected = 1/(2*n)
got, _ = fixed_quad(lambda x: x**(2*n - 1), 0, 1, n=n)
# quadrature exact for this input
assert_allclose(got, expected, rtol=1e-12)
def test_vector(self):
n = 4
p = np.arange(1, 2*n)
expected = 1/(p + 1)
got, _ = fixed_quad(lambda x: x**p[:, None], 0, 1, n=n)
assert_allclose(got, expected, rtol=1e-12)
class TestQuadrature:
def quad(self, x, a, b, args):
raise NotImplementedError
def test_quadrature(self):
# Typical function with two extra arguments:
def myfunc(x, n, z): # Bessel function integrand
return cos(n*x-z*sin(x))/pi
val, err = quadrature(myfunc, 0, pi, (2, 1.8))
table_val = 0.30614353532540296487
assert_almost_equal(val, table_val, decimal=7)
def test_quadrature_rtol(self):
def myfunc(x, n, z): # Bessel function integrand
return 1e90 * cos(n*x-z*sin(x))/pi
val, err = quadrature(myfunc, 0, pi, (2, 1.8), rtol=1e-10)
table_val = 1e90 * 0.30614353532540296487
assert_allclose(val, table_val, rtol=1e-10)
def test_quadrature_miniter(self):
# Typical function with two extra arguments:
def myfunc(x, n, z): # Bessel function integrand
return cos(n*x-z*sin(x))/pi
table_val = 0.30614353532540296487
for miniter in [5, 52]:
val, err = quadrature(myfunc, 0, pi, (2, 1.8), miniter=miniter)
assert_almost_equal(val, table_val, decimal=7)
assert_(err < 1.0)
def test_quadrature_single_args(self):
def myfunc(x, n):
return 1e90 * cos(n*x-1.8*sin(x))/pi
val, err = quadrature(myfunc, 0, pi, args=2, rtol=1e-10)
table_val = 1e90 * 0.30614353532540296487
assert_allclose(val, table_val, rtol=1e-10)
def test_romberg(self):
# Typical function with two extra arguments:
def myfunc(x, n, z): # Bessel function integrand
return cos(n*x-z*sin(x))/pi
val = romberg(myfunc, 0, pi, args=(2, 1.8))
table_val = 0.30614353532540296487
assert_almost_equal(val, table_val, decimal=7)
def test_romberg_rtol(self):
# Typical function with two extra arguments:
def myfunc(x, n, z): # Bessel function integrand
return 1e19*cos(n*x-z*sin(x))/pi
val = romberg(myfunc, 0, pi, args=(2, 1.8), rtol=1e-10)
table_val = 1e19*0.30614353532540296487
assert_allclose(val, table_val, rtol=1e-10)
def test_romb(self):
assert_equal(romb(np.arange(17)), 128)
def test_romb_gh_3731(self):
# Check that romb makes maximal use of data points
x = np.arange(2**4+1)
y = np.cos(0.2*x)
val = romb(y)
val2, err = quad(lambda x: np.cos(0.2*x), x.min(), x.max())
assert_allclose(val, val2, rtol=1e-8, atol=0)
# should be equal to romb with 2**k+1 samples
with suppress_warnings() as sup:
sup.filter(AccuracyWarning, "divmax .4. exceeded")
val3 = romberg(lambda x: np.cos(0.2*x), x.min(), x.max(), divmax=4)
assert_allclose(val, val3, rtol=1e-12, atol=0)
def test_non_dtype(self):
# Check that we work fine with functions returning float
import math
valmath = romberg(math.sin, 0, 1)
expected_val = 0.45969769413185085
assert_almost_equal(valmath, expected_val, decimal=7)
def test_newton_cotes(self):
"""Test the first few degrees, for evenly spaced points."""
n = 1
wts, errcoff = newton_cotes(n, 1)
assert_equal(wts, n*np.array([0.5, 0.5]))
assert_almost_equal(errcoff, -n**3/12.0)
n = 2
wts, errcoff = newton_cotes(n, 1)
assert_almost_equal(wts, n*np.array([1.0, 4.0, 1.0])/6.0)
assert_almost_equal(errcoff, -n**5/2880.0)
n = 3
wts, errcoff = newton_cotes(n, 1)
assert_almost_equal(wts, n*np.array([1.0, 3.0, 3.0, 1.0])/8.0)
assert_almost_equal(errcoff, -n**5/6480.0)
n = 4
wts, errcoff = newton_cotes(n, 1)
assert_almost_equal(wts, n*np.array([7.0, 32.0, 12.0, 32.0, 7.0])/90.0)
assert_almost_equal(errcoff, -n**7/1935360.0)
def test_newton_cotes2(self):
"""Test newton_cotes with points that are not evenly spaced."""
x = np.array([0.0, 1.5, 2.0])
y = x**2
wts, errcoff = newton_cotes(x)
exact_integral = 8.0/3
numeric_integral = np.dot(wts, y)
assert_almost_equal(numeric_integral, exact_integral)
x = np.array([0.0, 1.4, 2.1, 3.0])
y = x**2
wts, errcoff = newton_cotes(x)
exact_integral = 9.0
numeric_integral = np.dot(wts, y)
assert_almost_equal(numeric_integral, exact_integral)
def test_simpson(self):
y = np.arange(17)
assert_equal(simpson(y), 128)
assert_equal(simpson(y, dx=0.5), 64)
assert_equal(simpson(y, x=np.linspace(0, 4, 17)), 32)
y = np.arange(4)
x = 2**y
assert_equal(simpson(y, x=x, even='avg'), 13.875)
assert_equal(simpson(y, x=x, even='first'), 13.75)
assert_equal(simpson(y, x=x, even='last'), 14)
# Tests for checking base case
x = np.array([3])
y = np.power(x, 2)
assert_equal(simpson(y, x=x, axis=0), 0.0)
assert_equal(simpson(y, x=x, axis=-1), 0.0)
x = np.array([3, 3, 3, 3])
y = np.power(x, 2)
assert_equal(simpson(y, x=x, axis=0), 0.0)
assert_equal(simpson(y, x=x, axis=-1), 0.0)
x = np.array([[1, 2, 4, 8], [1, 2, 4, 8], [1, 2, 4, 8]])
y = np.power(x, 2)
zero_axis = [0.0, 0.0, 0.0, 0.0]
default_axis = [175.75, 175.75, 175.75]
assert_equal(simpson(y, x=x, axis=0), zero_axis)
assert_equal(simpson(y, x=x, axis=-1), default_axis)
x = np.array([[1, 2, 4, 8], [1, 2, 4, 8], [1, 8, 16, 32]])
y = np.power(x, 2)
zero_axis = [0.0, 136.0, 1088.0, 8704.0]
default_axis = [175.75, 175.75, 11292.25]
assert_equal(simpson(y, x=x, axis=0), zero_axis)
assert_equal(simpson(y, x=x, axis=-1), default_axis)
@pytest.mark.parametrize('droplast', [False, True])
def test_simpson_2d_integer_no_x(self, droplast):
# The inputs are 2d integer arrays. The results should be
# identical to the results when the inputs are floating point.
y = np.array([[2, 2, 4, 4, 8, 8, -4, 5],
[4, 4, 2, -4, 10, 22, -2, 10]])
if droplast:
y = y[:, :-1]
result = simpson(y, axis=-1)
expected = simpson(np.array(y, dtype=np.float64), axis=-1)
assert_equal(result, expected)
def test_simps(self):
# Basic coverage test for the alias
y = np.arange(4)
x = 2**y
assert_equal(simpson(y, x=x, dx=0.5, even='first'),
simps(y, x=x, dx=0.5, even='first'))
class TestCumulative_trapezoid:
def test_1d(self):
x = np.linspace(-2, 2, num=5)
y = x
y_int = cumulative_trapezoid(y, x, initial=0)
y_expected = [0., -1.5, -2., -1.5, 0.]
assert_allclose(y_int, y_expected)
y_int = cumulative_trapezoid(y, x, initial=None)
assert_allclose(y_int, y_expected[1:])
def test_y_nd_x_nd(self):
x = np.arange(3 * 2 * 4).reshape(3, 2, 4)
y = x
y_int = cumulative_trapezoid(y, x, initial=0)
y_expected = np.array([[[0., 0.5, 2., 4.5],
[0., 4.5, 10., 16.5]],
[[0., 8.5, 18., 28.5],
[0., 12.5, 26., 40.5]],
[[0., 16.5, 34., 52.5],
[0., 20.5, 42., 64.5]]])
assert_allclose(y_int, y_expected)
# Try with all axes
shapes = [(2, 2, 4), (3, 1, 4), (3, 2, 3)]
for axis, shape in zip([0, 1, 2], shapes):
y_int = cumulative_trapezoid(y, x, initial=3.45, axis=axis)
assert_equal(y_int.shape, (3, 2, 4))
y_int = cumulative_trapezoid(y, x, initial=None, axis=axis)
assert_equal(y_int.shape, shape)
def test_y_nd_x_1d(self):
y = np.arange(3 * 2 * 4).reshape(3, 2, 4)
x = np.arange(4)**2
# Try with all axes
ys_expected = (
np.array([[[4., 5., 6., 7.],
[8., 9., 10., 11.]],
[[40., 44., 48., 52.],
[56., 60., 64., 68.]]]),
np.array([[[2., 3., 4., 5.]],
[[10., 11., 12., 13.]],
[[18., 19., 20., 21.]]]),
np.array([[[0.5, 5., 17.5],
[4.5, 21., 53.5]],
[[8.5, 37., 89.5],
[12.5, 53., 125.5]],
[[16.5, 69., 161.5],
[20.5, 85., 197.5]]]))
for axis, y_expected in zip([0, 1, 2], ys_expected):
y_int = cumulative_trapezoid(y, x=x[:y.shape[axis]], axis=axis,
initial=None)
assert_allclose(y_int, y_expected)
def test_x_none(self):
y = np.linspace(-2, 2, num=5)
y_int = cumulative_trapezoid(y)
y_expected = [-1.5, -2., -1.5, 0.]
assert_allclose(y_int, y_expected)
y_int = cumulative_trapezoid(y, initial=1.23)
y_expected = [1.23, -1.5, -2., -1.5, 0.]
assert_allclose(y_int, y_expected)
y_int = cumulative_trapezoid(y, dx=3)
y_expected = [-4.5, -6., -4.5, 0.]
assert_allclose(y_int, y_expected)
y_int = cumulative_trapezoid(y, dx=3, initial=1.23)
y_expected = [1.23, -4.5, -6., -4.5, 0.]
assert_allclose(y_int, y_expected)
def test_cumtrapz(self):
# Basic coverage test for the alias
x = np.arange(3 * 2 * 4).reshape(3, 2, 4)
y = x
assert_allclose(cumulative_trapezoid(y, x, dx=0.5, axis=0, initial=0),
cumtrapz(y, x, dx=0.5, axis=0, initial=0),
rtol=1e-14)
class TestTrapezoid():
"""This function is tested in NumPy more extensive, just do some
basic due diligence here."""
def test_trapezoid(self):
y = np.arange(17)
assert_equal(trapezoid(y), 128)
assert_equal(trapezoid(y, dx=0.5), 64)
assert_equal(trapezoid(y, x=np.linspace(0, 4, 17)), 32)
y = np.arange(4)
x = 2**y
assert_equal(trapezoid(y, x=x, dx=0.1), 13.5)
def test_trapz(self):
# Basic coverage test for the alias
y = np.arange(4)
x = 2**y
assert_equal(trapezoid(y, x=x, dx=0.5, axis=0),
trapz(y, x=x, dx=0.5, axis=0))
class TestQMCQuad():
def test_input_validation(self):
message = "`func` must be callable."
with pytest.raises(TypeError, match=message):
qmc_quad("a duck", [0, 0], [1, 1])
message = "`func` must evaluate the integrand at points..."
with pytest.raises(ValueError, match=message):
qmc_quad(lambda: 1, [0, 0], [1, 1])
def func(x):
assert x.ndim == 1
return np.sum(x)
message = "Exception encountered when attempting vectorized call..."
with pytest.warns(UserWarning, match=message):
qmc_quad(func, [0, 0], [1, 1])
message = "`n_points` must be an integer."
with pytest.raises(TypeError, match=message):
qmc_quad(lambda x: 1, [0, 0], [1, 1], n_points=1024.5)
message = "`n_estimates` must be an integer."
with pytest.raises(TypeError, match=message):
qmc_quad(lambda x: 1, [0, 0], [1, 1], n_estimates=8.5)
message = "`qrng` must be an instance of scipy.stats.qmc.QMCEngine."
with pytest.raises(TypeError, match=message):
qmc_quad(lambda x: 1, [0, 0], [1, 1], qrng="a duck")
message = "`qrng` must be initialized with dimensionality equal to "
with pytest.raises(ValueError, match=message):
qmc_quad(lambda x: 1, [0, 0], [1, 1], qrng=stats.qmc.Sobol(1))
message = r"`log` must be boolean \(`True` or `False`\)."
with pytest.raises(TypeError, match=message):
qmc_quad(lambda x: 1, [0, 0], [1, 1], log=10)
def basic_test(self, n_points=2**8, n_estimates=8, signs=np.ones(2)):
ndim = 2
mean = np.zeros(ndim)
cov = np.eye(ndim)
def func(x):
return stats.multivariate_normal.pdf(x, mean, cov)
rng = np.random.default_rng(2879434385674690281)
qrng = stats.qmc.Sobol(ndim, seed=rng)
a = np.zeros(ndim)
b = np.ones(ndim) * signs
res = qmc_quad(func, a, b, n_points=n_points,
n_estimates=n_estimates, args=(mean, cov), qrng=qrng)
ref = stats.multivariate_normal.cdf(b, mean, cov, lower_limit=a)
atol = sc.stdtrit(n_estimates-1, 0.995) * res.standard_error # 99% CI
assert_allclose(res.integral, ref, atol=atol)
assert np.prod(signs)*res.integral > 0
rng = np.random.default_rng(2879434385674690281)
qrng = stats.qmc.Sobol(ndim, seed=rng)
logres = qmc_quad(lambda *args: np.log(func(*args)), a, b,
n_points=n_points, n_estimates=n_estimates,
args=(mean, cov), log=True, qrng=qrng)
assert_allclose(np.exp(logres.integral), res.integral)
assert np.imag(logres.integral) == (np.pi if np.prod(signs) < 0 else 0)
@pytest.mark.parametrize("n_points", [2**8, 2**12])
@pytest.mark.parametrize("n_estimates", [8, 16])
def test_basic(self, n_points, n_estimates):
self.basic_test(n_points, n_estimates)
@pytest.mark.parametrize("signs", [[1, 1], [-1, -1], [-1, 1], [1, -1]])
def test_sign(self, signs):
self.basic_test(signs=signs)
@pytest.mark.parametrize("log", [False, True])
def test_zero(self, log):
message = "A lower limit was equal to an upper limit, so"
with pytest.warns(UserWarning, match=message):
res = qmc_quad(lambda x: 1, [0, 0], [0, 1], log=log)
assert res.integral == (-np.inf if log else 0)
assert res.standard_error == 0
def test_flexible_input(self):
# check that qrng is not required
# also checks that for 1d problems, a and b can be scalars
def func(x):
return stats.norm.pdf(x, scale=2)
res = qmc_quad(func, 0, 1)
ref = stats.norm.cdf(1, scale=2) - stats.norm.cdf(0, scale=2)
assert_allclose(res.integral, ref, 1e-2)