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#!/usr/bin/env python
# encoding: utf-8
"""
Author(s): Matthew Loper
See LICENCE.txt for licensing and contact information.
"""
import numpy as np
import unittest
from .ch import Ch
class TestLinalg(unittest.TestCase):
def setUp(self):
np.random.seed(0)
def test_slogdet(self):
from . import ch
tmp = ch.random.randn(100).reshape((10,10))
# print 'chumpy version: ' + str(slogdet(tmp)[1].r)
# print 'old version:' + str(np.linalg.slogdet(tmp.r)[1])
eps = 1e-10
diff = np.random.rand(100) * eps
diff_reshaped = diff.reshape((10,10))
gt = np.linalg.slogdet(tmp.r+diff_reshaped)[1] - np.linalg.slogdet(tmp.r)[1]
pred = ch.linalg.slogdet(tmp)[1].dr_wrt(tmp).dot(diff)
#print gt
#print pred
diff = gt - pred
self.assertTrue(np.max(np.abs(diff)) < 1e-12)
sgn_gt = np.linalg.slogdet(tmp.r)[0]
sgn_pred = ch.linalg.slogdet(tmp)[0]
#print sgn_gt
#print sgn_pred
diff = sgn_gt - sgn_pred.r
self.assertTrue(np.max(np.abs(diff)) < 1e-12)
def test_lstsq(self):
from .linalg import lstsq
shapes = ([10, 3], [3, 10])
for shape in shapes:
for b2d in True, False:
A = (np.random.rand(np.prod(shape))-.5).reshape(shape)
if b2d:
b = np.random.randn(shape[0],2)
else:
b = np.random.randn(shape[0])
x1, residuals1, rank1, s1 = lstsq(A, b)
x2, residuals2, rank2, s2 = np.linalg.lstsq(A, b)
#print x1.r
#print x2
#print residuals1.r
#print residuals2
self.assertTrue(np.max(np.abs(x1.r-x2)) < 1e-14)
if len(residuals2) > 0:
self.assertTrue(np.max(np.abs(residuals1.r-residuals2)) < 1e-14)
def test_pinv(self):
from .linalg import Pinv
data = (np.random.rand(12)-.5).reshape((3, 4))
pc_tall = Pinv(data)
pc_wide = Pinv(data.T)
pn_tall = np.linalg.pinv(data)
pn_wide = np.linalg.pinv(data.T)
tall_correct = np.max(np.abs(pc_tall.r - pn_tall)) < 1e-12
wide_correct = np.max(np.abs(pc_wide.r - pn_wide)) < 1e-12
# if not tall_correct or not wide_correct:
# print tall_correct
# print wide_correct
# import pdb; pdb.set_trace()
self.assertTrue(tall_correct)
self.assertTrue(wide_correct)
return # FIXME. how to test derivs?
for pc in [pc_tall, pc_wide]:
self.chkd(pc, pc.mtx)
import pdb; pdb.set_trace()
def test_svd(self):
from .linalg import Svd
eps = 1e-3
idx = 10
data = np.sin(np.arange(300)*100+10).reshape((-1,3))
data[3,:] = data[3,:]*0+10
data[:,1] *= 2
data[:,2] *= 4
data = data.copy()
u,s,v = np.linalg.svd(data, full_matrices=False)
data = Ch(data)
data2 = data.r.copy()
data2.ravel()[idx] += eps
u2,s2,v2 = np.linalg.svd(data2, full_matrices=False)
svdu, svdd, svdv = Svd(x=data)
# test singular values
diff_emp = (s2-s) / eps
diff_pred = svdd.dr_wrt(data)[:,idx]
#print diff_emp
#print diff_pred
ratio = diff_emp / diff_pred
#print ratio
self.assertTrue(np.max(np.abs(ratio - 1.)) < 1e-4)
# test V
diff_emp = (v2 - v) / eps
diff_pred = svdv.dr_wrt(data)[:,idx].reshape(diff_emp.shape)
ratio = diff_emp / diff_pred
#print ratio
self.assertTrue(np.max(np.abs(ratio - 1.)) < 1e-2)
# test U
diff_emp = (u2 - u) / eps
diff_pred = svdu.dr_wrt(data)[:,idx].reshape(diff_emp.shape)
ratio = diff_emp / diff_pred
#print ratio
self.assertTrue(np.max(np.abs(ratio - 1.)) < 1e-2)
def test_det(self):
from .linalg import Det
mtx1 = Ch(np.sin(2**np.arange(9)).reshape((3,3)))
mtx1_det = Det(mtx1)
dr = mtx1_det.dr_wrt(mtx1)
eps = 1e-5
mtx2 = mtx1.r.copy()
input_diff = np.sin(np.arange(mtx2.size)).reshape(mtx2.shape) * eps
mtx2 += input_diff
mtx2_det = Det(mtx2)
output_diff_emp = (np.linalg.det(mtx2) - np.linalg.det(mtx1.r)).ravel()
output_diff_pred = Det(mtx1).dr_wrt(mtx1).dot(input_diff.ravel())
#print output_diff_emp
#print output_diff_pred
self.assertTrue(np.max(np.abs(output_diff_emp - output_diff_pred)) < eps*1e-4)
self.assertTrue(np.max(np.abs(mtx1_det.r - np.linalg.det(mtx1.r)).ravel()) == 0)
def test_inv1(self):
from .linalg import Inv
mtx1 = Ch(np.sin(2**np.arange(9)).reshape((3,3)))
mtx1_inv = Inv(mtx1)
dr = mtx1_inv.dr_wrt(mtx1)
eps = 1e-5
mtx2 = mtx1.r.copy()
input_diff = np.sin(np.arange(mtx2.size)).reshape(mtx2.shape) * eps
mtx2 += input_diff
mtx2_inv = Inv(mtx2)
output_diff_emp = (np.linalg.inv(mtx2) - np.linalg.inv(mtx1.r)).ravel()
output_diff_pred = Inv(mtx1).dr_wrt(mtx1).dot(input_diff.ravel())
#print output_diff_emp
#print output_diff_pred
self.assertTrue(np.max(np.abs(output_diff_emp - output_diff_pred)) < eps*1e-4)
self.assertTrue(np.max(np.abs(mtx1_inv.r - np.linalg.inv(mtx1.r)).ravel()) == 0)
def test_inv2(self):
from .linalg import Inv
eps = 1e-8
idx = 13
mtx1 = np.random.rand(100).reshape((10,10))
mtx2 = mtx1.copy()
mtx2.ravel()[idx] += eps
diff_emp = (np.linalg.inv(mtx2) - np.linalg.inv(mtx1)) / eps
mtx1 = Ch(mtx1)
diff_pred = Inv(mtx1).dr_wrt(mtx1)[:,13].reshape(diff_emp.shape)
#print diff_emp
#print diff_pred
#print diff_emp - diff_pred
self.assertTrue(np.max(np.abs(diff_pred.ravel()-diff_emp.ravel())) < 1e-4)
@unittest.skipIf(np.__version__ < '1.8',
"broadcasting for matrix inverse not supported in numpy < 1.8")
def test_inv3(self):
"""Test linalg.inv with broadcasting support."""
from .linalg import Inv
mtx1 = Ch(np.sin(2**np.arange(12)).reshape((3,2,2)))
mtx1_inv = Inv(mtx1)
dr = mtx1_inv.dr_wrt(mtx1)
eps = 1e-5
mtx2 = mtx1.r.copy()
input_diff = np.sin(np.arange(mtx2.size)).reshape(mtx2.shape) * eps
mtx2 += input_diff
mtx2_inv = Inv(mtx2)
output_diff_emp = (np.linalg.inv(mtx2) - np.linalg.inv(mtx1.r)).ravel()
output_diff_pred = Inv(mtx1).dr_wrt(mtx1).dot(input_diff.ravel())
# print output_diff_emp
# print output_diff_pred
self.assertTrue(np.max(np.abs(output_diff_emp.ravel() - output_diff_pred.ravel())) < eps*1e-3)
self.assertTrue(np.max(np.abs(mtx1_inv.r - np.linalg.inv(mtx1.r)).ravel()) == 0)
def chkd(self, obj, parm, eps=1e-14):
backed_up = parm.x
if True:
diff = (np.random.rand(parm.size)-.5).reshape(parm.shape)
else:
diff = np.zeros(parm.shape)
diff.ravel()[4] = 2.
dr = obj.dr_wrt(parm)
parm.x = backed_up - diff*eps
r_lower = obj.r
parm.x = backed_up + diff*eps
r_upper = obj.r
diff_emp = (r_upper - r_lower) / (eps*2.)
diff_pred = dr.dot(diff.ravel()).reshape(diff_emp.shape)
#print diff_emp
#print diff_pred
print(diff_emp / diff_pred)
print(diff_emp - diff_pred)
parm.x = backed_up
suite = unittest.TestLoader().loadTestsFromTestCase(TestLinalg)
if __name__ == '__main__':
unittest.main()
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