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t_two_term_approximation.py
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t_two_term_approximation.py
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from builtins import range
import numpy as np
from gpkit import Variable, Model
from copy import copy
import unittest
from gpkit.tests.helpers import run_tests
from robust.twoterm_approximation import TwoTermApproximation
from robust.testing.models import gp_test_model, sp_test_model
from robust.twoterm_approximation import TwoTermApproximation
class TestTwoTermApproximation(unittest.TestCase):
def test_equivalent_twoterm_model(self):
gpmodel = gp_test_model()
equivalent_constraints = []
for c in gpmodel.flat():
equivalent_constraints += TwoTermApproximation.equivalent_posynomial(c.unsubbed[0], 0, [], True)[1]
twoterm_gpmodel = Model(gpmodel.cost, [equivalent_constraints], gpmodel.substitutions)
self.assertAlmostEqual(gpmodel.solve(verbosity=0)['cost'],twoterm_gpmodel.solve(verbosity=0)['cost'])
# def test_two_term_approx(self):
# m = gp_test_model()
# settings = {}
# tta = [TwoTermApproximation(i.unsubbed[0], {}) for i in m.flat()]
# tta_smart = [TwoTermApproximation(i.unsubbed[0],
# {'smartTwoTermChoose': True}) for i in m.flat()]
def test_check_if_permutation_exists(self):
for _ in range(10):
number_of_monomials = int(np.random.rand()*15) + 3
number_of_permutations = TwoTermApproximation.total_number_of_permutations(number_of_monomials)
number_of_gp_variables = int(np.random.rand()*20) + 1
m = [np.random.rand()*10 for _ in range(number_of_monomials)]
for j in range(number_of_monomials):
for i in range(number_of_gp_variables):
x = Variable('x_%s' % i)
m[j] *= x**(np.random.rand()*10 - 5)
p = sum(m)
permutation_list = list(range(0, number_of_monomials))
list_of_permutations = []
list_of_posynomials = []
counter = 0
while counter < min(100, int(np.floor(number_of_permutations/2))):
temp = copy(permutation_list)
np.random.shuffle(temp)
if TwoTermApproximation.check_if_permutation_exists(list_of_permutations, temp):
continue
else:
list_of_permutations.append(temp)
_, data_constraints = TwoTermApproximation.equivalent_posynomial(p, 1, temp, False)
data_posynomial = [constraint.unsubbed[0]*Variable("z^%s_%s" % (i, 1))
for i, constraint in enumerate(data_constraints)]
list_of_posynomials.append(list(data_posynomial))
counter += 1
# counter = 0
#
# while counter < min(100, int(np.floor(number_of_permutations/2))):
# temp = copy(permutation_list)
# np.random.shuffle(temp)
#
# flag_one = TwoTermApproximation.check_if_permutation_exists(list_of_permutations, temp)
# _, data_constraints = TwoTermApproximation.equivalent_posynomial(p, 1, temp, False)
# data_posynomial = [constraint.unsubbed[0]*Variable("z^%s_%s" % (i, 1))
# for i, constraint in enumerate(data_constraints)]
# flag_two = list(data_posynomial) in list_of_posynomials
#
# assert (flag_one == flag_two)
# counter += 1
def test_bad_relations(self):
for _ in range(30):
number_of_monomials = int(20*np.random.random()) + 3
number_of_gp_variables = int(np.random.rand()*10) + 1
number_of_additional_uncertain_variables = int(np.random.rand()*5) + 1
vector_to_choose_from_pos_only = [0, 0, 1, 0, 0, 0, 0, 0, 1, 0]
m = [np.random.rand()*10 for _ in range(number_of_monomials)]
p_uncertain_vars = []
relations = {}
sizes = {}
neg_pos_neutral_powers = []
for j in range(number_of_monomials):
for i in range(number_of_gp_variables):
x = Variable('x_%s' % i)
m[j] *= x**(np.random.rand()*10 - 5)
number_of_elements_in_relation = min(number_of_monomials,
int(number_of_monomials*np.random.rand()+2))
all_elements = []
for _ in range(number_of_elements_in_relation):
element = np.random.choice(list(range(0, number_of_monomials)))
while element in all_elements:
element = np.random.choice(list(range(0, number_of_monomials)))
all_elements.append(element)
element_map = {}
number_of_element_map_elements = min(number_of_monomials - 1,
int(number_of_monomials*np.random.rand()+2))
for _ in range(number_of_element_map_elements):
element_map_element = int(np.random.rand()*number_of_monomials)
while element_map_element in element_map or element_map_element == element:
element_map_element = int(np.random.rand()*number_of_monomials)
size = int(number_of_monomials*np.random.rand())+1
element_map[element_map_element] = size
try:
relations[element_map_element][element] = size
except:
relations[element_map_element] = {element: size}
if element in relations:
relations[element].update(element_map)
else:
relations[element] = element_map
relations_copy = {}
for key in list(relations.keys()):
relations_copy[key] = copy(relations[key])
sizes[key] = len(relations[key])
counter = 0
while relations_copy:
keys = list(relations_copy.keys())
for key in keys:
if not relations_copy[key]:
del relations_copy[key]
continue
u = Variable('u_%s' % counter, np.random.random(), pr=100*np.random.random())
counter += 1
p_uncertain_vars.append(u.key)
el_pow = np.random.choice([-1, 1])
m[key] *= u**(np.random.rand()*5*el_pow)
element_keys = list(relations_copy[key].keys())
for element_key in element_keys:
m[element_key] *= u**(-np.random.rand()*5*el_pow)
relations_copy[key][element_key] -= 1
if relations_copy[key][element_key] == 0:
del relations_copy[key][element_key]
relations_copy[element_key][key] -= 1
if relations_copy[element_key][key] == 0:
del relations_copy[element_key][key]
for i in range(number_of_additional_uncertain_variables):
u = Variable('u_%s' % counter, np.random.random(), pr=100*np.random.random())
counter += 1
p_uncertain_vars.append(u.key)
el_pow = np.random.choice([-1, 1])
neg_pos_neutral_powers.append([el_pow*vector_to_choose_from_pos_only[int(10*np.random.random())]
for _ in range(number_of_monomials)])
for j in range(number_of_monomials):
m[j] *= u**(np.random.rand()*5*neg_pos_neutral_powers[i][j])
p = sum(m)
monomials = p.chop()
actual_relations, actual_sizes = TwoTermApproximation.bad_relations(p)
keys = list(actual_relations.keys())
actual_relations_mons = {}
actual_sizes_mons = {}
for key in keys:
internal_map = actual_relations[key]
map_keys = list(internal_map.keys())
map_mons = {}
for map_key in map_keys:
map_mons[monomials[map_key]] = internal_map[map_key]
actual_relations_mons[monomials[key]] = map_mons
actual_sizes_mons[monomials[key]] = actual_sizes[key]
keys = list(relations.keys())
relations_mons = {}
sizes_mons = {}
for key in keys:
internal_map = relations[key]
map_keys = list(internal_map.keys())
map_mons = {}
for map_key in map_keys:
map_mons[m[map_key]] = internal_map[map_key]
relations_mons[m[key]] = map_mons
sizes_mons[m[key]] = sizes[key]
self.assertEqual(actual_relations_mons, relations_mons)
self.assertEqual(sizes_mons, actual_sizes_mons)
TESTS = [TestTwoTermApproximation]
def test():
run_tests(TESTS)
if __name__ == "__main__":
test()