def test_hermediv(self):
for i in range(5):
for j in range(5):
msg = "At i=%d, j=%d" % (i, j)
ci = [0] * i + [1]
cj = [0] * j + [1]
tgt = herme.hermeadd(ci, cj)
quo, rem = herme.hermediv(tgt, ci)
res = herme.hermeadd(herme.hermemul(quo, ci), rem)
assert_equal(trim(res), trim(tgt), err_msg=msg)
def test_hermediv(self) :
for i in range(5) :
for j in range(5) :
msg = "At i=%d, j=%d" % (i,j)
ci = [0]*i + [1]
cj = [0]*j + [1]
tgt = herme.hermeadd(ci, cj)
quo, rem = herme.hermediv(tgt, ci)
res = herme.hermeadd(herme.hermemul(quo, ci), rem)
assert_equal(trim(res), trim(tgt), err_msg=msg)
def test_hermemul(self):
# check values of result
for i in range(5):
pol1 = [0] * i + [1]
val1 = herme.hermeval(self.x, pol1)
for j in range(5):
msg = "At i=%d, j=%d" % (i, j)
pol2 = [0] * j + [1]
val2 = herme.hermeval(self.x, pol2)
pol3 = herme.hermemul(pol1, pol2)
val3 = herme.hermeval(self.x, pol3)
assert_(len(pol3) == i + j + 1, msg)
assert_almost_equal(val3, val1 * val2, err_msg=msg)
def test_hermemul(self) :
# check values of result
for i in range(5) :
pol1 = [0]*i + [1]
val1 = herme.hermeval(self.x, pol1)
for j in range(5) :
msg = "At i=%d, j=%d" % (i,j)
pol2 = [0]*j + [1]
val2 = herme.hermeval(self.x, pol2)
pol3 = herme.hermemul(pol1, pol2)
val3 = herme.hermeval(self.x, pol3)
assert_(len(pol3) == i + j + 1, msg)
assert_almost_equal(val3, val1*val2, err_msg=msg)
def product3_herm(i,j,l):
#compute \Phi_i*\Phi_j*\Phi_l
return lambda x: H.hermeval(x, H.hermemul(H.hermemul(Phi(i),Phi(j)),Phi(l)))
