def test_create_swap_index(self): settings = Settings.instance() # Market information calendar = TARGET() # must be a business day eval_date = calendar.adjust(today()) settings.evaluation_date = eval_date settlement_days = 2 settlement_date = calendar.advance(eval_date, settlement_days, Days) # must be a business day settlement_date = calendar.adjust(settlement_date) term_structure = YieldTermStructure(relinkable=True) term_structure.link_to( FlatForward(settlement_date, 0.05, Actual365Fixed())) ibor_index = Libor('USD Libor', Period(6, Months), settlement_days, USDCurrency(), calendar, Actual360(), term_structure) index = SwapIndex('family name', Period(3, Months), 10, USDCurrency(), TARGET(), Period(12, Months), Following, Actual360(), ibor_index) self.assertIsNotNone(index)
def test_create_swap_rate_helper_from_index(self): calendar = UnitedStates() settlement_days = 2 currency = USDCurrency() fixed_leg_tenor = Period(12, Months) fixed_leg_convention = ModifiedFollowing fixed_leg_daycounter = Actual360() family_name = currency.name + 'index' ibor_index = Libor( "USDLibor", Period(3,Months), settlement_days, USDCurrency(), UnitedStates(), Actual360() ) rate = SimpleQuote(0.005681) tenor = Period(1, Years) index = SwapIndex ( family_name, tenor, settlement_days, currency, calendar, fixed_leg_tenor, fixed_leg_convention, fixed_leg_daycounter, ibor_index) helper_from_quote = SwapRateHelper.from_index(rate, index) helper_from_float = SwapRateHelper.from_index(0.005681, index) #self.fail( # 'Make this pass: create and ask for the .quote property' # ' Test the from_index and from_tenor methods' #) self.assertIsNotNone(helper_from_quote, helper_from_float) self.assertAlmostEqual(rate.value, helper_from_quote.quote.value) self.assertAlmostEqual(helper_from_float.quote.value, helper_from_quote.quote.value) with self.assertRaises(RuntimeError): self.assertAlmostEqual(rate.value, helper_from_quote.implied_quote)
def test_create_swap_rate_helper_from_tenor(self): calendar = UnitedStates() settlement_days = 2 rate = SimpleQuote(0.005681) ibor_index = Libor("USDLibor", Period(3, Months), settlement_days, USDCurrency(), UnitedStates(), Actual360()) helper_from_quote = SwapRateHelper.from_tenor(rate, Period(12, Months), calendar, Annual, ModifiedFollowing, Actual360(), ibor_index) helper_from_float = SwapRateHelper.from_tenor(0.005681, Period(12, Months), calendar, Annual, ModifiedFollowing, Actual360(), ibor_index) self.assertIsNotNone(helper_from_float, helper_from_quote) self.assertEqual(rate.value, helper_from_quote.quote.value) self.assertEqual(helper_from_quote.quote.value, helper_from_float.quote.value) with self.assertRaises(RuntimeError): self.assertAlmostEqual(rate.value, helper_from_quote.implied_quote)
def test_create_libor_index(self): settings = Settings.instance() # Market information calendar = TARGET() # must be a business day eval_date = calendar.adjust(today()) settings.evaluation_date = eval_date settlement_days = 2 settlement_date = calendar.advance(eval_date, settlement_days, Days) # must be a business day settlement_date = calendar.adjust(settlement_date) term_structure = YieldTermStructure(relinkable=True) term_structure.link_to( FlatForward(settlement_date, 0.05, Actual365Fixed())) index = Libor('USD Libor', Period(6, Months), settlement_days, USDCurrency(), calendar, Actual360(), term_structure) t = index.tenor self.assertEquals(t.length, 6) self.assertEquals(t.units, 2) self.assertEquals('USD Libor6M Actual/360', index.name)
def test_create_libor_index(self): settings = Settings.instance() # Market information calendar = UnitedStates(LiborImpact) # must be a business day eval_date = calendar.adjust(today()) settings.evaluation_date = eval_date settlement_days = 2 settlement_date = calendar.advance(eval_date, settlement_days, Days) # must be a business day settlement_date = calendar.adjust(settlement_date) term_structure = YieldTermStructure(relinkable=True) term_structure.link_to( FlatForward(settlement_date, 0.05, Actual365Fixed())) index = Libor('USDLibor', Period(6, Months), settlement_days, USDCurrency(), calendar, Actual360(), term_structure) default_libor = USDLibor(Period(6, Months)) for attribute in [ "business_day_convention", "end_of_month", "fixing_calendar", "joint_calendar", "tenor", "fixing_days", "day_counter", "family_name", "name" ]: self.assertEqual(getattr(index, attribute), getattr(default_libor, attribute))
def build_helpers(): calendar = TARGET() settlement_days = 2 depositData = [[1, Months, 'Libor1M', 5.32], [3, Months, 'Libor3M', 5.35], [6, Months, 'Libor6M', 5.35]] swapData = [[1, Years, 'Swap1Y', 5.31], [2, Years, 'Swap2Y', 5.06], [3, Years, 'Swap3Y', 5.00], [4, Years, 'Swap4Y', 5.01], [5, Years, 'Swap5Y', 5.04], [7, Years, 'Swap7Y', 5.12], [10, Years, 'Swap10Y', 5.22], [30, Years, 'Swap30Y', 5.44]] rate_helpers = [] end_of_month = True for m, _, _, rate in depositData: tenor = Period(m, Months) helper = DepositRateHelper(SimpleQuote(rate / 100.0), tenor, settlement_days, calendar, ModifiedFollowing, end_of_month, Actual360()) rate_helpers.append(helper) liborIndex = Libor('USD Libor', Period(3, Months), settlement_days, USDCurrency(), calendar, Actual360()) spread = SimpleQuote(0) fwdStart = Period(0, Days) for m, _, _, rate in swapData: helper = SwapRateHelper.from_tenor( SimpleQuote(rate / 100.0), Period(m, Years), calendar, Semiannual, ModifiedFollowing, Thirty360(), liborIndex, spread, fwdStart) rate_helpers.append(helper) return rate_helpers
def make_rate_helper(label, rate, dt_obs, currency='USD'): """ Wrapper for deposit and swaps rate helpers makers For Swaps: assume USD swap fixed rates vs. 6M Libor TODO: make this more general """ if(currency.upper() != 'USD'): raise Exception("Only supported currency is USD.") rate_type, tenor, period = _parse_rate_label(label) if not isinstance(dt_obs, Date): dt_obs = pydate_to_qldate(dt_obs) settings = Settings() calendar = JointCalendar(UnitedStates(), UnitedKingdom()) # must be a business day eval_date = calendar.adjust(dt_obs) settings.evaluation_date = eval_date settlement_days = 2 settlement_date = calendar.advance(eval_date, settlement_days, Days) # must be a business day settlement_date = calendar.adjust(settlement_date) end_of_month = True if((rate_type == 'SWAP') & (period == 'Y')): liborIndex = Libor( 'USD Libor', Period(6, Months), settlement_days, USDCurrency(), calendar, Actual360() ) spread = SimpleQuote(0) fwdStart = Period(0, Days) helper = SwapRateHelper.from_tenor(rate, Period(tenor, Years), calendar, Annual, Unadjusted, Thirty360(), liborIndex, spread, fwdStart) elif((rate_type == 'LIBOR') & (period == 'M')): helper = DepositRateHelper(rate, Period(tenor, Months), settlement_days, calendar, ModifiedFollowing, end_of_month, Actual360()) else: raise Exception("Rate type %s not supported" % label) return (helper)
def test_create_swap_index(self): term_structure = YieldTermStructure() term_structure.link_to( FlatForward(forward=0.05, daycounter=Actual365Fixed(), settlement_days=2, calendar=UnitedStates())) ibor_index = USDLibor(Period(3, Months), term_structure) index = SwapIndex('UsdLiborSwapIsdaFixAm', Period(10, Years), 2, USDCurrency(), UnitedStates(GovernmentBond), Period(6, Months), ModifiedFollowing, Thirty360(), ibor_index) index2 = UsdLiborSwapIsdaFixAm(Period(10, Years), term_structure) for attr in [ 'name', 'family_name', 'fixing_calendar', 'tenor', 'day_counter', 'currency' ]: self.assertEqual(getattr(index, attr), getattr(index2, attr))
def test_from_name(self): cu_1 = Currency.from_name('USD') cu_2 = USDCurrency() self.assertEquals(cu_1.name, cu_2.name) self.assertIsInstance(cu_1, USDCurrency)
def test_zero_curve(self): try: settings = Settings() calendar = TARGET() # must be a business Days dtObs = date(2007, 4, 27) eval_date = calendar.adjust(pydate_to_qldate(dtObs)) settings.evaluation_date = eval_date settlement_days = 2 settlement_date = calendar.advance(eval_date, settlement_days, Days) # must be a business day settlement_date = calendar.adjust(settlement_date) print('dt Obs: %s\ndt Eval: %s\ndt Settle: %s' % (dtObs, eval_date, settlement_date)) depositData = [[1, Months, 'Libor1M', 5.32], [3, Months, 'Libor3M', 5.35], [6, Months, 'Libor6M', 5.35]] swapData = [[1, Years, 'Swap1Y', 5.31], [2, Years, 'Swap2Y', 5.06], [3, Years, 'Swap3Y', 5.00], [4, Years, 'Swap4Y', 5.01], [5, Years, 'Swap5Y', 5.04], [7, Years, 'Swap7Y', 5.12], [10, Years, 'Swap10Y', 5.22], [30, Years, 'Swap30Y', 5.44]] rate_helpers = [] end_of_month = True for m, period, label, rate in depositData: tenor = Period(m, Months) helper = DepositRateHelper(SimpleQuote(rate / 100.0), tenor, settlement_days, calendar, ModifiedFollowing, end_of_month, Actual360()) rate_helpers.append(helper) liborIndex = Libor('USD Libor', Period(3, Months), settlement_days, USDCurrency(), calendar, Actual360()) spread = SimpleQuote(0) fwdStart = Period(0, Days) for m, period, label, rate in swapData: helper = SwapRateHelper.from_tenor(SimpleQuote(rate / 100.0), Period(m, Years), calendar, Semiannual, ModifiedFollowing, Thirty360(), liborIndex, spread, fwdStart) rate_helpers.append(helper) ts_day_counter = ActualActual(ISDA) tolerance = 1.0e-2 ts = PiecewiseYieldCurve('discount', 'loglinear', settlement_date, rate_helpers, ts_day_counter, tolerance) # max_date raises an exception... dtMax = ts.max_date print('max date: %s' % dtMax) except RuntimeError as e: print('Exception (expected):\n%s' % e) self.assertTrue(True) except Exception: self.assertFalse()
def test_display(self): settings = Settings() # Date setup calendar = TARGET() # Settlement date settlement_date = calendar.adjust(Date(28, January, 2011)) # Evaluation date fixing_days = 1 settlement_days = 1 todays_date = calendar.advance( settlement_date, -fixing_days, Days ) settings.evaluation_date = todays_date # Bound attributes face_amount = 100.0 redemption = 100.0 issue_date = Date(27, January, 2011) maturity_date = Date(31, August, 2020) coupon_rate = 0.03625 bond_yield = 0.034921 flat_discounting_term_structure = YieldTermStructure() flat_term_structure = FlatForward( reference_date = settlement_date, forward = bond_yield, daycounter = Actual365Fixed(), #actual_actual.ActualActual(actual_actual.Bond), compounding = Compounded, frequency = Semiannual) # have a look at the FixedRateBondHelper to simplify this # construction flat_discounting_term_structure.link_to(flat_term_structure) #Rate fixed_bond_schedule = Schedule( issue_date, maturity_date, Period(Semiannual), UnitedStates(market=GOVERNMENTBOND), Unadjusted, Unadjusted, Backward, False); bond = FixedRateBond( settlement_days, face_amount, fixed_bond_schedule, [coupon_rate], ActualActual(Bond), Unadjusted, redemption, issue_date ) d=bf.startDate(bond) zspd=bf.zSpread(bond, 100.0, flat_term_structure, Actual365Fixed(), Compounded, Semiannual, settlement_date, 1e-6, 100, 0.5) #Also need a test case for a PiecewiseTermStructure... depositData = [[ 1, Months, 4.581 ], [ 2, Months, 4.573 ], [ 3, Months, 4.557 ], [ 6, Months, 4.496 ], [ 9, Months, 4.490 ]] swapData = [[ 1, Years, 4.54 ], [ 5, Years, 4.99 ], [ 10, Years, 5.47 ], [ 20, Years, 5.89 ], [ 30, Years, 5.96 ]] rate_helpers = [] end_of_month = True for m, period, rate in depositData: tenor = Period(m, Months) helper = DepositRateHelper(SimpleQuote(rate/100), tenor, settlement_days, calendar, ModifiedFollowing, end_of_month, Actual360()) rate_helpers.append(helper) liborIndex = Libor('USD Libor', Period(6, Months), settlement_days, USDCurrency(), calendar, Actual360(), YieldTermStructure(relinkable=False)) spread = SimpleQuote(0) fwdStart = Period(0, Days) for m, period, rate in swapData: helper = SwapRateHelper.from_tenor( SimpleQuote(rate/100), Period(m, Years), calendar, Annual, Unadjusted, Thirty360(), liborIndex, spread, fwdStart ) rate_helpers.append(helper) ts_day_counter = ActualActual(ISDA) tolerance = 1.0e-15 ts = PiecewiseYieldCurve.from_reference_date( BootstrapTrait.Discount, Interpolator.LogLinear, settlement_date, rate_helpers, ts_day_counter, tolerance) pyc_zspd=bf.zSpread(bond, 102.0, ts, ActualActual(ISDA), Compounded, Semiannual, Date(1, April, 2015), 1e-6, 100, 0.5) pyc_zspd_disco=bf.zSpread(bond, 95.0, ts, ActualActual(ISDA), Compounded, Semiannual, settlement_date, 1e-6, 100, 0.5) yld = bf.yld(bond, 102.0, ActualActual(ISDA), Compounded, Semiannual, settlement_date, 1e-6, 100, 0.5) dur = bf.duration(bond, yld, ActualActual(ISDA), Compounded, Semiannual, 2, settlement_date) yld_disco = bf.yld(bond, 95.0, ActualActual(ISDA), Compounded, Semiannual, settlement_date, 1e-6, 100, 0.5) dur_disco = bf.duration(bond, yld_disco, ActualActual(ISDA), Compounded, Semiannual, 2, settlement_date) self.assertEqual(round(zspd, 6), 0.001281) self.assertEqual(round(pyc_zspd, 4), -0.0264) self.assertEqual(round(pyc_zspd_disco, 4), -0.0114) self.assertEqual(round(yld, 4), 0.0338) self.assertEqual(round(yld_disco, 4), 0.0426) self.assertEqual(round(dur, 4), 8.0655) self.assertEqual(round(dur_disco, 4), 7.9702)
def dividendOption(): # ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ # ++++++++++++++++++++ General Parameter for all the computation +++++++++++++++++++++++ # ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ # declaration of the today's date (date where the records are done) todaysDate = Date(24, Jan, 2012) # INPUT Settings.instance( ).evaluation_date = todaysDate #!\ IMPORTANT COMMAND REQUIRED FOR ALL VALUATIONS calendar = UnitedStates() # INPUT settlement_days = 2 # INPUT # Calcul of the settlement date : need to add a period of 2 days to the todays date settlementDate = calendar.advance(todaysDate, period=Period(settlement_days, Days)) dayCounter = Actual360() # INPUT currency = USDCurrency() # INPUT print("Date of the evaluation: ", todaysDate) print("Calendar used: ", calendar.name) print("Number of settlement Days: ", settlement_days) print("Date of settlement: ", settlementDate) print("Convention of day counter: ", dayCounter.name()) print("Currency of the actual context:\t\t", currency.name) # ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ # ++++++++++++++++++++ Description of the underlying +++++++++++++++++++++++++++++++++++ # ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ underlying_name = "IBM" underlying_price = 191.75 # INPUT underlying_vol = 0.2094 # INPUT print("**********************************") print("Name of the underlying: ", underlying_name) print("Price of the underlying at t0: ", underlying_price) print("Volatility of the underlying: ", underlying_vol) # For a great managing of price and vol objects --> Handle underlying_priceH = SimpleQuote(underlying_price) # We suppose the vol constant : his term structure is flat --> BlackConstantVol object flatVolTS = BlackConstantVol(settlementDate, calendar, underlying_vol, dayCounter) # ++++++++++++++++++++ Description of Yield Term Structure # Libor data record print("**********************************") print("Description of the Libor used for the Yield Curve construction") Libor_dayCounter = Actual360() liborRates = [] liborRatesTenor = [] # INPUT : all the following data are input : the rate and the corresponding tenor # You could make the choice of more or less data # --> However you have tho choice the instruments with different maturities liborRates = [ 0.002763, 0.004082, 0.005601, 0.006390, 0.007125, 0.007928, 0.009446, 0.01110 ] liborRatesTenor = [ Period(tenor, Months) for tenor in [1, 2, 3, 4, 5, 6, 9, 12] ] for tenor, rate in zip(liborRatesTenor, liborRates): print(tenor, "\t\t\t", rate) # Swap data record # description of the fixed leg of the swap Swap_fixedLegTenor = Period(12, Months) # INPUT Swap_fixedLegConvention = ModifiedFollowing # INPUT Swap_fixedLegDayCounter = Actual360() # INPUT # description of the float leg of the swap Swap_iborIndex = Libor("USDLibor", Period(3, Months), settlement_days, USDCurrency(), UnitedStates(), Actual360()) print("Description of the Swap used for the Yield Curve construction") print("Tenor of the fixed leg: ", Swap_fixedLegTenor) print("Index of the floated leg: ", Swap_iborIndex.name) print("Maturity Rate ") swapRates = [] swapRatesTenor = [] # INPUT : all the following data are input : the rate and the corresponding tenor # You could make the choice of more or less data # --> However you have tho choice the instruments with different maturities swapRates = [ 0.005681, 0.006970, 0.009310, 0.012010, 0.014628, 0.016881, 0.018745, 0.020260, 0.021545 ] swapRatesTenor = [Period(i, Years) for i in range(2, 11)] for tenor, rate in zip(swapRatesTenor, swapRates): print(tenor, "\t\t\t", rate) # ++++++++++++++++++++ Creation of the vector of RateHelper (need for the Yield Curve construction) # ++++++++++++++++++++ Libor LiborFamilyName = currency.name + "Libor" instruments = [] for rate, tenor in zip(liborRates, liborRatesTenor): # Index description ___ creation of a Libor index liborIndex = Libor(LiborFamilyName, tenor, settlement_days, currency, calendar, Libor_dayCounter) # Initialize rate helper ___ the DepositRateHelper link the recording rate with the Libor index instruments.append(DepositRateHelper(rate, index=liborIndex)) # +++++++++++++++++++++ Swap SwapFamilyName = currency.name + "swapIndex" for tenor, rate in zip(swapRatesTenor, swapRates): # swap description ___ creation of a swap index. The floating leg is described in the index 'Swap_iborIndex' swapIndex = SwapIndex(SwapFamilyName, tenor, settlement_days, currency, calendar, Swap_fixedLegTenor, Swap_fixedLegConvention, Swap_fixedLegDayCounter, Swap_iborIndex) # Initialize rate helper __ the SwapRateHelper links the swap index width his rate instruments.append(SwapRateHelper.from_index(rate, swapIndex)) # ++++++++++++++++++ Now the creation of the yield curve riskFreeTS = PiecewiseYieldCurve.from_reference_date( BootstrapTrait.ZeroYield, Interpolator.Linear, settlementDate, instruments, dayCounter) # ++++++++++++++++++ build of the underlying process : with a Black-Scholes model print('Creating process') bsProcess = BlackScholesProcess(underlying_priceH, riskFreeTS, flatVolTS) # ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ # ++++++++++++++++++++ Description of the option +++++++++++++++++++++++++++++++++++++++ # ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ Option_name = "IBM Option" maturity = Date(26, Jan, 2013) strike = 190 option_type = 'call' # Here, as an implementation exemple, we make the test with borth american and european exercise europeanExercise = EuropeanExercise(maturity) # The emericanExercise need also the settlement date, as his right to exerce the buy or call start at the settlement date! #americanExercise = AmericanExercise(settlementDate, maturity) americanExercise = AmericanExercise(maturity, settlementDate) print("**********************************") print("Description of the option: ", Option_name) print("Date of maturity: ", maturity) print("Type of the option: ", option_type) print("Strike of the option: ", strike) # ++++++++++++++++++ Description of the discrete dividends # INPUT You have to determine the frequece and rates of the discrete dividend. Here is a sollution, but she's not the only one. # Last know dividend: dividend = 0.75 #//0.75 next_dividend_date = Date(10, Feb, 2012) # HERE we have make the assumption that the dividend will grow with the quarterly croissance: dividendCroissance = 1.03 dividendfrequence = Period(3, Months) dividendDates = [] dividends = [] d = next_dividend_date while d <= maturity: dividendDates.append(d) dividends.append(dividend) d = d + dividendfrequence dividend *= dividendCroissance print("Discrete dividends ") print("Dates Dividends ") for date, div in zip(dividendDates, dividends): print(date, " ", div) # ++++++++++++++++++ Description of the final payoff payoff = PlainVanillaPayoff(option_type, strike) # ++++++++++++++++++ The OPTIONS : (American and European) with their dividends description: dividendEuropeanOption = DividendVanillaOption(payoff, europeanExercise, dividendDates, dividends) dividendAmericanOption = DividendVanillaOption(payoff, americanExercise, dividendDates, dividends) # just too test europeanOption = VanillaOption(payoff, europeanExercise) americanOption = VanillaOption(payoff, americanExercise) # ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ # ++++++++++++++++++++ Description of the pricing +++++++++++++++++++++++++++++++++++++ # ++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ # For the european options we have a closed analytic formula: The Black Scholes: dividendEuropeanEngine = AnalyticDividendEuropeanEngine(bsProcess) # For the american option we have make the choice of the finite difference model with the CrankNicolson scheme # this model need to precise the time and space step # More they are greater, more the calul will be precise. americanGirdPoints = 600 americanTimeSteps = 600 dividendAmericanEngine = FDDividendAmericanEngine('CrankNicolson', bsProcess, americanTimeSteps, americanGirdPoints) # just to test europeanEngine = AnalyticEuropeanEngine(bsProcess) americanEngine = FDAmericanEngine('CrankNicolson', bsProcess, americanTimeSteps, americanGirdPoints) # ++++++++++++++++++++ Valorisation ++++++++++++++++++++++++++++++++++++++++ # Link the pricing Engine to the option dividendEuropeanOption.set_pricing_engine(dividendEuropeanEngine) dividendAmericanOption.set_pricing_engine(dividendAmericanEngine) # just to test europeanOption.set_pricing_engine(europeanEngine) americanOption.set_pricing_engine(americanEngine) # Now we make all the needing calcul # ... and final results print( "NPV of the European Option with discrete dividends=0: {:.4f}".format( dividendEuropeanOption.npv)) print("NPV of the European Option without dividend: {:.4f}".format( europeanOption.npv)) print( "NPV of the American Option with discrete dividends=0: {:.4f}".format( dividendAmericanOption.npv)) print("NPV of the American Option without dividend: {:.4f}".format( americanOption.npv)) # just a single test print("ZeroRate with a maturity at ", maturity, ": ", \ riskFreeTS.zero_rate(maturity, dayCounter, Simple))
def test_swap_QL(self): """ Test that a swap with fixed coupon = fair rate has an NPV=0 Create from QL objects """ nominal = 100.0 fixedConvention = Unadjusted floatingConvention = ModifiedFollowing fixedFrequency = Annual floatingFrequency = Semiannual fixedDayCount = Thirty360() floatDayCount = Thirty360() calendar = TARGET() settlement_days = 2 eval_date = Date(2, January, 2014) settings = Settings() settings.evaluation_date = eval_date settlement_date = calendar.advance(eval_date, settlement_days, Days) # must be a business day settlement_date = calendar.adjust(settlement_date) termStructure = YieldTermStructure(relinkable=True) termStructure.link_to( FlatForward(settlement_date, 0.05, Actual365Fixed())) index = Libor('USD Libor', Period(6, Months), settlement_days, USDCurrency(), calendar, Actual360(), termStructure) length = 5 fixedRate = .05 floatingSpread = 0.0 maturity = calendar.advance(settlement_date, length, Years, convention=floatingConvention) fixedSchedule = Schedule(settlement_date, maturity, Period(fixedFrequency), calendar, fixedConvention, fixedConvention, Rule.Forward, False) floatSchedule = Schedule(settlement_date, maturity, Period(floatingFrequency), calendar, floatingConvention, floatingConvention, Rule.Forward, False) engine = DiscountingSwapEngine(termStructure, False, settlement_date, settlement_date) for swap_type in [Payer, Receiver]: swap = VanillaSwap(swap_type, nominal, fixedSchedule, fixedRate, fixedDayCount, floatSchedule, index, floatingSpread, floatDayCount, fixedConvention) swap.set_pricing_engine(engine) fixed_leg = swap.fixed_leg floating_leg = swap.floating_leg f = swap.fair_rate print('fair rate: %f' % f) p = swap.net_present_value print('NPV: %f' % p) swap = VanillaSwap(swap_type, nominal, fixedSchedule, f, fixedDayCount, floatSchedule, index, floatingSpread, floatDayCount, fixedConvention) swap.set_pricing_engine(engine) p = swap.net_present_value print('NPV: %f' % p) self.assertAlmostEqual(p, 0)
def test_zero_curve_on_swap_index(self): todays_date = today() calendar = UnitedStates() # INPUT dayCounter = Actual360() # INPUT currency = USDCurrency() # INPUT Settings.instance().evaluation_date = todays_date settlement_days = 2 settlement_date = calendar.advance( todays_date, period=Period(settlement_days, Days) ) liborRates = [ SimpleQuote(0.002763), SimpleQuote(0.004082), SimpleQuote(0.005601), SimpleQuote(0.006390), SimpleQuote(0.007125), SimpleQuote(0.007928), SimpleQuote(0.009446), SimpleQuote(0.01110)] liborRatesTenor = [Period(tenor, Months) for tenor in [1,2,3,4,5,6,9,12]] Libor_dayCounter = Actual360(); swapRates = [SimpleQuote(0.005681), SimpleQuote(0.006970), SimpleQuote(0.009310), SimpleQuote(0.012010), SimpleQuote(0.014628), SimpleQuote(0.016881), SimpleQuote(0.018745), SimpleQuote(0.020260), SimpleQuote(0.021545)] swapRatesTenor = [Period(i, Years) for i in range(2, 11)] # description of the fixed leg of the swap Swap_fixedLegTenor = Period(12, Months) # INPUT Swap_fixedLegConvention = ModifiedFollowing # INPUT Swap_fixedLegDayCounter = Actual360() # INPUT # description of the float leg of the swap Swap_iborIndex = Libor( "USDLibor", Period(3, Months), settlement_days, USDCurrency(), UnitedStates(), Actual360() ) SwapFamilyName = currency.name + "swapIndex" instruments = [] # ++++++++++++++++++++ Creation of the vector of RateHelper (need for the Yield Curve construction) # ++++++++++++++++++++ Libor LiborFamilyName = currency.name + "Libor" instruments = [] for rate, tenor in zip(liborRates, liborRatesTenor): # Index description ___ creation of a Libor index liborIndex = Libor( LiborFamilyName, tenor, settlement_days, currency, calendar, Libor_dayCounter ) # Initialize rate helper # the DepositRateHelper link the recording rate with the Libor # index instruments.append(DepositRateHelper(rate, index=liborIndex)) for tenor, rate in zip(swapRatesTenor, swapRates): # swap description ___ creation of a swap index. The floating leg is described in the index 'Swap_iborIndex' swapIndex = SwapIndex ( SwapFamilyName, tenor, settlement_days, currency, calendar, Swap_fixedLegTenor, Swap_fixedLegConvention, Swap_fixedLegDayCounter, Swap_iborIndex ) # Initialize rate helper __ the SwapRateHelper links the swap index width his rate instruments.append(SwapRateHelper.from_index(rate,swapIndex)) # ++++++++++++++++++ Now the creation of the yield curve tolerance = 1.0e-15 ts = PiecewiseYieldCurve.from_reference_date( BootstrapTrait.ZeroYield, Interpolator.Linear, settlement_date, instruments, dayCounter, tolerance ) self.assertEqual(settlement_date, ts.reference_date)
def test_deposit_swap(self): settings = Settings() # Market information calendar = TARGET() todays_date = Date(1, Mar, 2012) # must be a business day eval_date = calendar.adjust(todays_date) settings.evaluation_date = eval_date settlement_days = 2 settlement_date = calendar.advance(eval_date, settlement_days, Days) # must be a business day settlement_date = calendar.adjust(settlement_date); depositData = [[ 1, Months, 4.581 ], [ 2, Months, 4.573 ], [ 3, Months, 4.557 ], [ 6, Months, 4.496 ], [ 9, Months, 4.490 ]] swapData = [[ 1, Years, 4.54 ], [ 5, Years, 4.99 ], [ 10, Years, 5.47 ], [ 20, Years, 5.89 ], [ 30, Years, 5.96 ]] rate_helpers = [] end_of_month = True for m, period, rate in depositData: tenor = Period(m, Months) helper = DepositRateHelper(SimpleQuote(rate/100), tenor, settlement_days, calendar, ModifiedFollowing, end_of_month, Actual360()) rate_helpers.append(helper) liborIndex = Libor( 'USD Libor', Period(6, Months), settlement_days, USDCurrency(), calendar, Actual360() ) spread = SimpleQuote(0) fwdStart = Period(0, Days) for m, period, rate in swapData: helper = SwapRateHelper.from_tenor( SimpleQuote(rate/100), Period(m, Years), calendar, Annual, Unadjusted, Thirty360(), liborIndex, spread, fwdStart ) rate_helpers.append(helper) ts_day_counter = ActualActual(ISDA) tolerance = 1.0e-15 ts = PiecewiseYieldCurve.from_reference_date( BootstrapTrait.Discount, Interpolator.LogLinear, settlement_date, rate_helpers, ts_day_counter, tolerance ) self.assertEqual(settlement_date, ts.reference_date) # this is not a real test ... self.assertAlmostEqual(0.9103, ts.discount(calendar.advance(todays_date, 2, Years)),3) self.assertAlmostEqual(0.7836, ts.discount(calendar.advance(todays_date, 5, Years)),3) self.assertAlmostEqual(0.5827, ts.discount(calendar.advance(todays_date, 10, Years)),3) self.assertAlmostEqual(0.4223, ts.discount(calendar.advance(todays_date, 15, Years)),3)
def get_term_structure(df_libor, dtObs): settings = Settings() # Market information calendar = TARGET() # must be a business day eval_date = calendar.adjust(dateToDate(dtObs)) settings.evaluation_date = eval_date settlement_days = 2 settlement_date = calendar.advance(eval_date, settlement_days, Days) # must be a business day settlement_date = calendar.adjust(settlement_date) depositData = [[1, Months, 'Libor1M'], [3, Months, 'Libor3M'], [6, Months, 'Libor6M']] swapData = [[1, Years, 'Swap1Y'], [2, Years, 'Swap2Y'], [3, Years, 'Swap3Y'], [4, Years, 'Swap4Y'], [5, Years, 'Swap5Y'], [7, Years, 'Swap7Y'], [10, Years, 'Swap10Y'], [30, Years, 'Swap30Y']] rate_helpers = [] end_of_month = True for m, period, label in depositData: tenor = Period(m, Months) rate = df_libor.get_value(dtObs, label) helper = DepositRateHelper(SimpleQuote(rate / 100.0), tenor, settlement_days, calendar, ModifiedFollowing, end_of_month, Actual360()) rate_helpers.append(helper) liborIndex = Libor('USD Libor', Period(3, Months), settlement_days, USDCurrency(), calendar, Actual360()) spread = SimpleQuote(0) fwdStart = Period(0, Days) for m, period, label in swapData: rate = df_libor.get_value(dtObs, label) helper = SwapRateHelper.from_tenor( SimpleQuote(rate / 100.0), Period(m, Years), calendar, Semiannual, ModifiedFollowing, Thirty360(), liborIndex, spread, fwdStart) rate_helpers.append(helper) ts_day_counter = ActualActual(ISDA) tolerance = 1.0e-15 ts = PiecewiseYieldCurve(BootstrapTrait.Discount, Interpolator.LogLinear, settlement_date, rate_helpers, ts_day_counter, tolerance) return ts
def test_bucketanalysis_bond(self): settings = Settings() calendar = TARGET() settlement_date = calendar.adjust(Date(28, January, 2011)) simple_quotes = [] fixing_days = 1 settlement_days = 1 todays_date = calendar.advance(settlement_date, -fixing_days, Days) settings.evaluation_date = todays_date face_amount = 100.0 redemption = 100.0 issue_date = Date(27, January, 2011) maturity_date = Date(1, January, 2021) coupon_rate = 0.055 bond_yield = 0.034921 flat_discounting_term_structure = YieldTermStructure() flat_term_structure = FlatForward(reference_date=settlement_date, forward=bond_yield, daycounter=Actual365Fixed(), compounding=Compounded, frequency=Semiannual) flat_discounting_term_structure.link_to(flat_term_structure) fixed_bond_schedule = Schedule.from_rule( issue_date, maturity_date, Period(Semiannual), UnitedStates(market=GovernmentBond), Unadjusted, Unadjusted, Backward, False) bond = FixedRateBond(settlement_days, face_amount, fixed_bond_schedule, [coupon_rate], ActualActual(Bond), Unadjusted, redemption, issue_date) zspd = bf.zSpread(bond, 100.0, flat_term_structure, Actual365Fixed(), Compounded, Semiannual, settlement_date, 1e-6, 100, 0.5) depositData = [[1, Months, 4.581], [2, Months, 4.573], [3, Months, 4.557], [6, Months, 4.496], [9, Months, 4.490]] swapData = [[1, Years, 4.54], [5, Years, 4.99], [10, Years, 5.47], [20, Years, 5.89], [30, Years, 5.96]] rate_helpers = [] end_of_month = True for m, period, rate in depositData: tenor = Period(m, Months) sq_rate = SimpleQuote(rate / 100) helper = DepositRateHelper(sq_rate, tenor, settlement_days, calendar, ModifiedFollowing, end_of_month, Actual360()) simple_quotes.append(sq_rate) rate_helpers.append(helper) liborIndex = Libor('USD Libor', Period(6, Months), settlement_days, USDCurrency(), calendar, Actual360()) spread = SimpleQuote(0) fwdStart = Period(0, Days) for m, period, rate in swapData: sq_rate = SimpleQuote(rate / 100) helper = SwapRateHelper.from_tenor(sq_rate, Period(m, Years), calendar, Annual, Unadjusted, Thirty360(), liborIndex, spread, fwdStart) simple_quotes.append(sq_rate) rate_helpers.append(helper) ts_day_counter = ActualActual(ISDA) tolerance = 1.0e-15 ts = PiecewiseYieldCurve.from_reference_date(BootstrapTrait.Discount, Interpolator.LogLinear, settlement_date, rate_helpers, ts_day_counter, tolerance) discounting_term_structure = YieldTermStructure() discounting_term_structure.link_to(ts) pricing_engine = DiscountingBondEngine(discounting_term_structure) bond.set_pricing_engine(pricing_engine) self.assertAlmostEqual(bond.npv, 100.83702940160767) ba = bucket_analysis([simple_quotes], [bond], [1], 0.0001, 1) self.assertTrue(2, ba) self.assertTrue(type(tuple), ba) self.assertEqual(len(simple_quotes), len(ba[0][0])) self.assertEqual(0, ba[0][0][8])