def test_raise(self):
d = HullWhiteCurveFactorModel(ZeroRateCurve())
f = HullWhiteCurveFactorModel(ZeroRateCurve())
x = HullWhiteFxRateFactorModel(FxRate(), d, f)
HullWhiteCurveFactorModel(ZeroRateCurve())
self.assertRaises(TypeError, HullWhiteCurveFactorModel, FxRate())
HullWhiteFxRateFactorModel(FxRate(), d, f)
self.assertRaises(TypeError, HullWhiteFxRateFactorModel,
ZeroRateCurve(), d, f)
self.assertRaises(TypeError, HullWhiteFxRateFactorModel, FxRate(),
ZeroRateCurve(), f)
self.assertRaises(TypeError, HullWhiteFxRateFactorModel, FxRate(), d,
ZeroRateCurve())
HullWhiteMultiCurrencyCurveFactorModel(f, d, x)
self.assertRaises(TypeError, HullWhiteMultiCurrencyCurveFactorModel, d,
f, FxRate())
self.assertRaises(TypeError, HullWhiteMultiCurrencyCurveFactorModel, d,
ZeroRateCurve(), x)
self.assertRaises(TypeError, HullWhiteMultiCurrencyCurveFactorModel,
ZeroRateCurve(), f, x)
HullWhiteCurve()
HullWhiteFxRate()
HullWhiteMultiCurrencyCurve()
def setUp(self):
self.today = _today
self.grid = _grid
self.termday = self.grid[-1]
self.flat_zero_curve = ZeroRateCurve([self.today], [0.05])
self.term_zero_curve = ZeroRateCurve(self.grid, _term)
self.zero_curve = self.flat_zero_curve
self.fx_curve = FxCurve([self.today], [1.],
domestic_curve=self.zero_curve,
foreign_curve=self.zero_curve)
self.fx_rate = FxRate(1., self.today)
self.fx_volatility = .3
self.gbm_fx_curve = GeometricBrownianMotionFxRateFactorModel(
self.fx_rate, volatility=self.fx_volatility)
self.mean_reversion = .1
self.volatility = .005
self.hull_white_curve = HullWhiteCurveFactorModel(
self.zero_curve, self.mean_reversion, self.volatility)
z = ZeroRateCurve([self.today], [0.03])
self.hull_white_curve_2 = HullWhiteCurveFactorModel(
z, self.mean_reversion * 2, self.volatility * 0.5)
self.df_func = (
lambda x: self.hull_white_curve.get_discount_factor(
x, self.termday) * self.hull_white_curve.inner_factor.
get_discount_factor(self.today, self.termday) / self.
hull_white_curve.inner_factor.get_discount_factor(x, self.termday))
self.fw_func = (
lambda x: self.hull_white_curve.get_cash_rate(self.termday - '1y'))
self.num_of_paths = 100
self.plot = dict()
def setUp(self):
self.today = _today
self.grid = _grid
self.termday = self.grid[-1]
self.flat_zero_curve = ZeroRateCurve([self.today], [0.05])
self.term_zero_curve = ZeroRateCurve(self.grid, _term)
self.zero_curve = self.flat_zero_curve
self.mean_reversion = .1
self.volatility = .005
self.hull_white_curve = HullWhiteCurveFactorModel(
self.zero_curve,
mean_reversion=self.mean_reversion,
volatility=self.volatility)
self.plot = dict()
def test_mean_reversion(self):
res = list()
res.append([
self.hull_white_curve.get_zero_rate(self.today, t)
for t in self.grid
])
for short_rate in [-.01, .0, .01]:
for mr in [0.01, 0.02, 0.05, 0.1, 0.2, 0.5]:
hwc = HullWhiteCurveFactorModel(self.zero_curve,
mean_reversion=mr,
volatility=self.volatility)
hwc.set_risk_factor(self.today + '1y', short_rate)
res.append(
[hwc.get_zero_rate(self.today, t) for t in self.grid])
self.plot['test_mean_reversion'] = res
self.assertTrue(True)
def test_volatility(self):
res = list()
res.append([
self.hull_white_curve.get_zero_rate(self.today, t)
for t in self.grid
])
for short_rate in [-.01, .0, .01]:
for v in [.005, .01, .05, .1]:
hwc = HullWhiteCurveFactorModel(
self.zero_curve,
mean_reversion=self.mean_reversion,
volatility=v)
hwc.set_risk_factor(self.today + '1y', short_rate)
res.append(
[hwc.get_zero_rate(self.today, t) for t in self.grid])
self.plot['test_volatility'] = res
self.assertTrue(True)
def test_multi_simulation(self):
res = list()
for vol in [.005, .01]:
for mr in [0.01, 0.1]:
hwc = HullWhiteCurveFactorModel(self.zero_curve,
mean_reversion=mr,
volatility=vol)
func = (lambda x: hwc.get_discount_factor(x, self.termday) *
hwc.get_discount_factor(self.today, x))
func = (lambda x: hwc.get_cash_rate(self.termday - '1y'))
producer = RiskFactorProducer(hwc)
fs_consumer = Consumer(lambda x: func(x.date))
avg_consumer = ValuationConsumer(func)
consumer = ConsumerConsumer([fs_consumer, avg_consumer])
# run the simulation
fs, avg = Engine(producer,
consumer).run(self.grid, self.num_of_paths)
res.append(avg)
self.plot['func sample v: %0.3f mr: %0.3f ' % (vol, mr)] = fs
self.plot['func avg'] = res
def setUp(self):
self.today = _today
self.grid = _grid
self.termday = self.grid[-1]
self.flat_zero_curve = ZeroRateCurve([self.today], [0.05])
self.term_zero_curve = ZeroRateCurve(self.grid, _term)
self.zero_curve = self.flat_zero_curve
self.mean_reversion = .1
self.volatility = .005
self.hull_white_curve = HullWhiteCurveFactorModel(
self.zero_curve,
mean_reversion=self.mean_reversion,
volatility=self.volatility)
self.df_func = (
lambda x: self.hull_white_curve.get_discount_factor(
x, self.termday) * self.hull_white_curve.inner_factor.
get_discount_factor(self.today, self.termday) / self.
hull_white_curve.inner_factor.get_discount_factor(x, self.termday))
self.fw_func = (
lambda x: self.hull_white_curve.get_cash_rate(self.termday - '1y'))
self.num_of_paths = 100
self.plot = dict()
class MultiCcyHullWhiteSimulationUnitTests(TestCase):
def setUp(self):
self.today = _today
self.grid = _grid
self.termday = self.grid[-1]
self.flat_zero_curve = ZeroRateCurve([self.today], [0.05])
self.term_zero_curve = ZeroRateCurve(self.grid, _term)
self.zero_curve = self.flat_zero_curve
self.fx_curve = FxCurve([self.today], [1.],
domestic_curve=self.zero_curve,
foreign_curve=self.zero_curve)
self.fx_rate = FxRate(1., self.today)
self.fx_volatility = .3
self.gbm_fx_curve = GeometricBrownianMotionFxRateFactorModel(
self.fx_rate, volatility=self.fx_volatility)
self.mean_reversion = .1
self.volatility = .005
self.hull_white_curve = HullWhiteCurveFactorModel(
self.zero_curve, self.mean_reversion, self.volatility)
z = ZeroRateCurve([self.today], [0.03])
self.hull_white_curve_2 = HullWhiteCurveFactorModel(
z, self.mean_reversion * 2, self.volatility * 0.5)
self.df_func = (
lambda x: self.hull_white_curve.get_discount_factor(
x, self.termday) * self.hull_white_curve.inner_factor.
get_discount_factor(self.today, self.termday) / self.
hull_white_curve.inner_factor.get_discount_factor(x, self.termday))
self.fw_func = (
lambda x: self.hull_white_curve.get_cash_rate(self.termday - '1y'))
self.num_of_paths = 100
self.plot = dict()
def tearDown(self):
_try_plot(self.plot, self.grid, self.today)
def test_simulation(self):
# setup timewave framework
corr = dict()
corr_list = list()
corr_list.append((.0, .0, .0))
corr_list.append((-.2, -.5, .7))
corr_list.append((.2, .5, .7))
corr_list.append((.2, .5, -.3))
corr_list.append((-.2, .5, -.3))
for dx, fx, df in corr_list:
corr[self.hull_white_curve, self.gbm_fx_curve] = dx
corr[self.hull_white_curve_2, self.gbm_fx_curve] = fx
corr[self.hull_white_curve, self.hull_white_curve_2] = df
hull_white_fx_curve = HullWhiteFxRateFactorModel(
self.gbm_fx_curve,
self.hull_white_curve,
self.hull_white_curve_2,
correlation=corr)
hull_white_mc_curve = HullWhiteMultiCurrencyCurveFactorModel(
self.hull_white_curve_2, self.hull_white_curve,
hull_white_fx_curve)
factors = [
self.hull_white_curve, hull_white_mc_curve, hull_white_fx_curve
]
# build producer
producer = MultiRiskFactorProducer(factors, corr)
# for fact in factors:
# print repr(fact) , repr(fact.diffusion_driver)
# for k, v in producer._driver_index.iteritems():
# print repr(k.process), v
# build consumer
consumer = MultiConsumer(Consumer(), Consumer(), Consumer())
# run engine
result = Engine(producer, consumer).run(self.grid,
self.num_of_paths)
c = repr((dx, fx, df))
self.plot['multi hull white d corr=%s' % c] = result[0]
self.plot['multi hull white f corr=%s' % c] = result[1]
self.plot['multi hull white x corr=%s' % c] = result[2]
def test_raise(self):
d = HullWhiteCurveFactorModel(ZeroRateCurve())
f = HullWhiteCurveFactorModel(ZeroRateCurve())
x = HullWhiteFxRateFactorModel(FxRate(), d, f)
HullWhiteCurveFactorModel(ZeroRateCurve())
self.assertRaises(TypeError, HullWhiteCurveFactorModel, FxRate())
HullWhiteFxRateFactorModel(FxRate(), d, f)
self.assertRaises(TypeError, HullWhiteFxRateFactorModel,
ZeroRateCurve(), d, f)
self.assertRaises(TypeError, HullWhiteFxRateFactorModel, FxRate(),
ZeroRateCurve(), f)
self.assertRaises(TypeError, HullWhiteFxRateFactorModel, FxRate(), d,
ZeroRateCurve())
HullWhiteMultiCurrencyCurveFactorModel(f, d, x)
self.assertRaises(TypeError, HullWhiteMultiCurrencyCurveFactorModel, d,
f, FxRate())
self.assertRaises(TypeError, HullWhiteMultiCurrencyCurveFactorModel, d,
ZeroRateCurve(), x)
self.assertRaises(TypeError, HullWhiteMultiCurrencyCurveFactorModel,
ZeroRateCurve(), f, x)
HullWhiteCurve()
HullWhiteFxRate()
HullWhiteMultiCurrencyCurve()
class HullWhiteSimulationUnitTests(TestCase):
def setUp(self):
self.today = _today
self.grid = _grid
self.termday = self.grid[-1]
self.flat_zero_curve = ZeroRateCurve([self.today], [0.05])
self.term_zero_curve = ZeroRateCurve(self.grid, _term)
self.zero_curve = self.flat_zero_curve
self.mean_reversion = .1
self.volatility = .005
self.hull_white_curve = HullWhiteCurveFactorModel(
self.zero_curve,
mean_reversion=self.mean_reversion,
volatility=self.volatility)
self.df_func = (
lambda x: self.hull_white_curve.get_discount_factor(
x, self.termday) * self.hull_white_curve.inner_factor.
get_discount_factor(self.today, self.termday) / self.
hull_white_curve.inner_factor.get_discount_factor(x, self.termday))
self.fw_func = (
lambda x: self.hull_white_curve.get_cash_rate(self.termday - '1y'))
self.num_of_paths = 100
self.plot = dict()
def tearDown(self):
_try_plot(self.plot, self.grid, self.today)
def test_simulation(self):
# setup timewave framework
producer = RiskFactorProducer(self.hull_white_curve)
x_consumer = Consumer(lambda x: x.value)
df_consumer = Consumer(lambda x: self.df_func(x.date))
pv_consumer = ValuationConsumer(self.df_func)
fw_consumer = Consumer(lambda x: self.fw_func(x.date))
af_consumer = ValuationConsumer(self.fw_func)
consumer = ConsumerConsumer(
[x_consumer, df_consumer, pv_consumer, fw_consumer, af_consumer])
# run the simulation
x, df_sim, df_avg, fwd_sim, fwd_avg = Engine(producer, consumer).run(
self.grid, self.num_of_paths)
# self.plot['state_avg'] = [[sum(xx) / len(xx) for xx in map(list, zip(*x))]]
# self.plot['state_path'] = x
self.plot['libor_avg'] = [
fwd_avg, [self.zero_curve.get_cash_rate(d) for d in self.grid]
]
self.plot['libor_path'] = fwd_sim
self.plot['df_avg'] = [
df_avg,
[
self.zero_curve.get_discount_factor(self.today, self.termday)
for d in self.grid
]
]
self.plot['df_path'] = df_sim
dfc = DiscountFactorCurve(self.grid, df_avg)
self.plot['zero_avg'] = [[
dfc.get_zero_rate(self.today, d) for d in self.grid
], [self.zero_curve.get_zero_rate(self.today, d) for d in self.grid]]
zr_list = list()
for dfs in df_sim:
dfc = DiscountFactorCurve(self.grid, dfs)
zr_list.append(
[dfc.get_zero_rate(self.today, d) for d in self.grid])
self.plot['zero_path'] = zr_list
def test_single_hull_white_model(self):
producer = RiskFactorProducer(self.hull_white_curve)
consumer = Consumer()
result = Engine(producer, consumer).run(self.grid, self.num_of_paths)
self.plot['single rf hull white'] = result
def test_multi_hull_white_model(self):
producer = MultiRiskFactorProducer([self.hull_white_curve])
consumer = MultiConsumer(Consumer())
result = Engine(producer, consumer).run(self.grid, self.num_of_paths)
self.plot['multi rf hull white'] = result[0]
def test_multi_simulation(self):
res = list()
for vol in [.005, .01]:
for mr in [0.01, 0.1]:
hwc = HullWhiteCurveFactorModel(self.zero_curve,
mean_reversion=mr,
volatility=vol)
func = (lambda x: hwc.get_discount_factor(x, self.termday) *
hwc.get_discount_factor(self.today, x))
func = (lambda x: hwc.get_cash_rate(self.termday - '1y'))
producer = RiskFactorProducer(hwc)
fs_consumer = Consumer(lambda x: func(x.date))
avg_consumer = ValuationConsumer(func)
consumer = ConsumerConsumer([fs_consumer, avg_consumer])
# run the simulation
fs, avg = Engine(producer,
consumer).run(self.grid, self.num_of_paths)
res.append(avg)
self.plot['func sample v: %0.3f mr: %0.3f ' % (vol, mr)] = fs
self.plot['func avg'] = res
class HullWhiteCurveUnitTests(TestCase):
def setUp(self):
self.today = _today
self.grid = _grid
self.termday = self.grid[-1]
self.flat_zero_curve = ZeroRateCurve([self.today], [0.05])
self.term_zero_curve = ZeroRateCurve(self.grid, _term)
self.zero_curve = self.flat_zero_curve
self.mean_reversion = .1
self.volatility = .005
self.hull_white_curve = HullWhiteCurveFactorModel(
self.zero_curve,
mean_reversion=self.mean_reversion,
volatility=self.volatility)
self.plot = dict()
def tearDown(self):
if __name__ == '__main__':
_try_plot(self.plot, self.grid, self.today)
def test_curve(self):
for d in self.grid:
zr = self.zero_curve.get_discount_factor(self.today, d)
hw = self.hull_white_curve.get_discount_factor(self.today, d)
self.assertAlmostEqual(zr, hw)
zr = self.zero_curve.get_discount_factor(d, self.termday)
hw = self.hull_white_curve.get_discount_factor(d, self.termday)
self.assertAlmostEqual(zr, hw)
zr = self.zero_curve.get_cash_rate(d)
hw = self.hull_white_curve.get_cash_rate(d)
self.assertAlmostEqual(zr, hw)
# assert self.zero_curve.get_discount_factor(self.today, d) == \
# self.hull_white_curve.get_discount_factor(self.today, d), \
# 'HullWhiteCurve fails at get_discount_factor(self.today, d) = get_discount_factor(%s, %s)' \
# % (str(self.today), str(d))
# assert self.zero_curve.get_discount_factor(d, self.termday) == \
# self.hull_white_curve.get_discount_factor(d, self.termday), \
# 'HullWhiteCurve fails at get_discount_factor(d, self.termday) = get_discount_factor(%s, %s)' \
# % (str(d), str(self.termday))
# assert self.zero_curve.get_cash_rate(d) == self.hull_white_curve.get_cash_rate(d), \
# 'HullWhiteCurve fails at get_cash_rate(d) = get_cash_rate(%s)' % (str(d))
if not self.today == d and not d == self.termday:
zr = self.zero_curve.get_zero_rate(self.today, d)
hw = self.hull_white_curve.get_zero_rate(self.today, d)
self.assertAlmostEqual(zr, hw)
zr = self.zero_curve.get_zero_rate(d, self.termday)
hw = self.hull_white_curve.get_zero_rate(d, self.termday)
self.assertAlmostEqual(zr, hw)
# assert self.zero_curve.get_zero_rate(self.today, d) == \
# self.hull_white_curve.get_zero_rate(self.today, d), \
# 'HullWhiteCurve fails at get_zero_rate(self.today, d) = get_zero_rate(%s, %s)' \
# % (str(self.today), str(d))
# assert self.zero_curve.get_zero_rate(d, self.termday) == \
# self.hull_white_curve.get_zero_rate(d, self.termday), \
# 'HullWhiteCurve fails at get_zero_rate(d, self.termday) = get_zero_rate(%s, %s)' \
# % (str(d), str(self.termday))
def test_short_rate(self):
res = list()
res.append([
self.hull_white_curve.get_zero_rate(self.today, t)
for t in self.grid
])
for short_rate in [-.01, .0, .01]:
self.hull_white_curve.set_risk_factor(self.today, short_rate)
res.append([
self.hull_white_curve.get_zero_rate(self.today, t)
for t in self.grid
])
res.append(
[self.hull_white_curve.get_cash_rate(t) for t in self.grid])
self.plot['test_short_rate'] = res
self.assertTrue(True)
def test_forward_rate(self):
res = list()
res.append([
self.hull_white_curve.get_zero_rate(self.today, t)
for t in self.grid
])
for short_rate in [-.01, .0, .01]:
for p in ['0d', '1y', '2y', '3y']:
self.hull_white_curve.set_risk_factor(self.today + p,
short_rate)
res.append([
self.hull_white_curve.get_zero_rate(self.today, t)
for t in self.grid
])
self.plot['test_forward_rate'] = res
self.assertTrue(True)
def test_mean_reversion(self):
res = list()
res.append([
self.hull_white_curve.get_zero_rate(self.today, t)
for t in self.grid
])
for short_rate in [-.01, .0, .01]:
for mr in [0.01, 0.02, 0.05, 0.1, 0.2, 0.5]:
hwc = HullWhiteCurveFactorModel(self.zero_curve,
mean_reversion=mr,
volatility=self.volatility)
hwc.set_risk_factor(self.today + '1y', short_rate)
res.append(
[hwc.get_zero_rate(self.today, t) for t in self.grid])
self.plot['test_mean_reversion'] = res
self.assertTrue(True)
def test_volatility(self):
res = list()
res.append([
self.hull_white_curve.get_zero_rate(self.today, t)
for t in self.grid
])
for short_rate in [-.01, .0, .01]:
for v in [.005, .01, .05, .1]:
hwc = HullWhiteCurveFactorModel(
self.zero_curve,
mean_reversion=self.mean_reversion,
volatility=v)
hwc.set_risk_factor(self.today + '1y', short_rate)
res.append(
[hwc.get_zero_rate(self.today, t) for t in self.grid])
self.plot['test_volatility'] = res
self.assertTrue(True)