//-------------------------------------------------------------------------
/// <summary>
/// Calculates the present value sensitivity of the Ibor caplet/floorlet to the rate curves.
/// <para>
/// The present value sensitivity is computed in a "sticky model parameter" style, i.e. the sensitivity to the
/// curve nodes with the SABR model parameters unchanged. This sensitivity does not include a potential
/// re-calibration of the model parameters to the raw market data.
///
/// </para>
/// </summary>
/// <param name="period"> the Ibor caplet/floorlet period </param>
/// <param name="ratesProvider"> the rates provider </param>
/// <param name="volatilities"> the volatilities </param>
/// <returns> the point sensitivity to the rate curves </returns>
public virtual PointSensitivityBuilder presentValueSensitivityRatesStickyModel(IborCapletFloorletPeriod period, RatesProvider ratesProvider, SabrIborCapletFloorletVolatilities volatilities)
{
Currency currency = period.Currency;
if (ratesProvider.ValuationDate.isAfter(period.PaymentDate))
{
return(PointSensitivityBuilder.none());
}
double expiry = volatilities.relativeTime(period.FixingDateTime);
PutCall putCall = period.PutCall;
double strike = period.Strike;
double indexRate = ratesProvider.iborIndexRates(period.Index).rate(period.IborRate.Observation);
PointSensitivityBuilder dfSensi = ratesProvider.discountFactors(currency).zeroRatePointSensitivity(period.PaymentDate);
double factor = period.Notional * period.YearFraction;
if (expiry < 0d)
{ // option expired already, but not yet paid
double sign = putCall.Call ? 1d : -1d;
double payoff = Math.Max(sign * (indexRate - strike), 0d);
return(dfSensi.multipliedBy(payoff * factor));
}
ValueDerivatives volatilityAdj = volatilities.volatilityAdjoint(expiry, strike, indexRate);
PointSensitivityBuilder indexRateSensiSensi = ratesProvider.iborIndexRates(period.Index).ratePointSensitivity(period.IborRate.Observation);
double df = ratesProvider.discountFactor(currency, period.PaymentDate);
double fwdPv = factor * volatilities.price(expiry, putCall, strike, indexRate, volatilityAdj.Value);
double fwdDelta = factor * volatilities.priceDelta(expiry, putCall, strike, indexRate, volatilityAdj.Value);
double fwdVega = factor * volatilities.priceVega(expiry, putCall, strike, indexRate, volatilityAdj.Value);
return(dfSensi.multipliedBy(fwdPv).combinedWith(indexRateSensiSensi.multipliedBy(fwdDelta * df + fwdVega * volatilityAdj.getDerivative(0) * df)));
}
//-------------------------------------------------------------------------
/// <summary>
/// Calculates the present value rates sensitivity of the Ibor caplet/floorlet.
/// <para>
/// The present value rates sensitivity of the caplet/floorlet is the sensitivity
/// of the present value to the underlying curves.
///
/// </para>
/// </summary>
/// <param name="period"> the Ibor caplet/floorlet period </param>
/// <param name="ratesProvider"> the rates provider </param>
/// <param name="volatilities"> the volatilities </param>
/// <returns> the present value curve sensitivity </returns>
public virtual PointSensitivityBuilder presentValueSensitivityRates(IborCapletFloorletPeriod period, RatesProvider ratesProvider, IborCapletFloorletVolatilities volatilities)
{
validate(volatilities);
Currency currency = period.Currency;
if (ratesProvider.ValuationDate.isAfter(period.PaymentDate))
{
return(PointSensitivityBuilder.none());
}
double expiry = volatilities.relativeTime(period.FixingDateTime);
PutCall putCall = period.PutCall;
double strike = period.Strike;
double indexRate = ratesProvider.iborIndexRates(period.Index).rate(period.IborRate.Observation);
PointSensitivityBuilder dfSensi = ratesProvider.discountFactors(currency).zeroRatePointSensitivity(period.PaymentDate);
if (expiry < 0d)
{ // Option has expired already
double sign = putCall.Call ? 1d : -1d;
double payoff = Math.Max(sign * (indexRate - strike), 0d);
return(dfSensi.multipliedBy(payoff * period.YearFraction * period.Notional));
}
PointSensitivityBuilder indexRateSensiSensi = ratesProvider.iborIndexRates(period.Index).ratePointSensitivity(period.IborRate.Observation);
double volatility = volatilities.volatility(expiry, strike, indexRate);
double df = ratesProvider.discountFactor(currency, period.PaymentDate);
double factor = period.Notional * period.YearFraction;
double fwdPv = factor * volatilities.price(expiry, putCall, strike, indexRate, volatility);
double fwdDelta = factor * volatilities.priceDelta(expiry, putCall, strike, indexRate, volatility);
return(dfSensi.multipliedBy(fwdPv).combinedWith(indexRateSensiSensi.multipliedBy(fwdDelta * df)));
}
/// <summary>
/// Calculates the par spread curve sensitivity for a swap.
/// <para>
/// The par spread is the common spread on all payments of the first leg for which the total swap present value is 0.
/// </para>
/// <para>
/// The par spread is computed with respect to the first leg. For that leg, all the payments have a unique
/// accrual period (no compounding) and no FX reset.
///
/// </para>
/// </summary>
/// <param name="swap"> the product </param>
/// <param name="provider"> the rates provider </param>
/// <returns> the par spread curve sensitivity of the swap product </returns>
public virtual PointSensitivityBuilder parSpreadSensitivity(ResolvedSwap swap, RatesProvider provider)
{
ResolvedSwapLeg referenceLeg = swap.Legs.get(0);
Currency ccyReferenceLeg = referenceLeg.Currency;
double convertedPv = presentValue(swap, ccyReferenceLeg, provider).Amount;
PointSensitivityBuilder convertedPvDr = presentValueSensitivity(swap, ccyReferenceLeg, provider);
// try one payment compounding, typically for inflation swaps
Triple <bool, int, double> fixedCompounded = checkFixedCompounded(referenceLeg);
if (fixedCompounded.First)
{
double df = provider.discountFactor(ccyReferenceLeg, referenceLeg.PaymentPeriods.get(0).PaymentDate);
PointSensitivityBuilder dfDr = provider.discountFactors(ccyReferenceLeg).zeroRatePointSensitivity(referenceLeg.PaymentPeriods.get(0).PaymentDate);
double referenceConvertedPv = legPricer.presentValue(referenceLeg, provider).Amount;
PointSensitivityBuilder referenceConvertedPvDr = legPricer.presentValueSensitivity(referenceLeg, provider);
double notional = ((RatePaymentPeriod)referenceLeg.PaymentPeriods.get(0)).Notional;
PointSensitivityBuilder dParSpreadDr = convertedPvDr.combinedWith(referenceConvertedPvDr.multipliedBy(-1)).multipliedBy(-1.0d / (df * notional)).combinedWith(dfDr.multipliedBy((convertedPv - referenceConvertedPv) / (df * df * notional))).multipliedBy(1.0d / fixedCompounded.Second * Math.Pow(-(convertedPv - referenceConvertedPv) / (df * notional) + 1.0d, 1.0d / fixedCompounded.Second - 1.0d));
return(dParSpreadDr);
}
double pvbp = legPricer.pvbp(referenceLeg, provider);
// Backward sweep
double convertedPvBar = -1d / pvbp;
double pvbpBar = convertedPv / (pvbp * pvbp);
PointSensitivityBuilder pvbpDr = legPricer.pvbpSensitivity(referenceLeg, provider);
return(convertedPvDr.multipliedBy(convertedPvBar).combinedWith(pvbpDr.multipliedBy(pvbpBar)));
}
//-------------------------------------------------------------------------
/// <summary>
/// Calculates the present value sensitivity of the swaption to the rate curves.
/// <para>
/// The present value sensitivity is computed in a "sticky strike" style, i.e. the sensitivity to the
/// curve nodes with the volatility at the swaption strike unchanged. This sensitivity does not include a potential
/// change of volatility due to the implicit change of forward rate or moneyness.
///
/// </para>
/// </summary>
/// <param name="swaption"> the swaption </param>
/// <param name="ratesProvider"> the rates provider </param>
/// <param name="swaptionVolatilities"> the volatilities </param>
/// <returns> the point sensitivity to the rate curves </returns>
public virtual PointSensitivityBuilder presentValueSensitivityRatesStickyStrike(ResolvedSwaption swaption, RatesProvider ratesProvider, SwaptionVolatilities swaptionVolatilities)
{
validate(swaption, ratesProvider, swaptionVolatilities);
double expiry = swaptionVolatilities.relativeTime(swaption.Expiry);
ResolvedSwap underlying = swaption.Underlying;
ResolvedSwapLeg fixedLeg = this.fixedLeg(underlying);
if (expiry < 0d)
{ // Option has expired already
return(PointSensitivityBuilder.none());
}
double forward = SwapPricer.parRate(underlying, ratesProvider);
double pvbp = SwapPricer.LegPricer.pvbp(fixedLeg, ratesProvider);
double strike = SwapPricer.LegPricer.couponEquivalent(fixedLeg, ratesProvider, pvbp);
double tenor = swaptionVolatilities.tenor(fixedLeg.StartDate, fixedLeg.EndDate);
double volatility = swaptionVolatilities.volatility(expiry, tenor, strike, forward);
PutCall putCall = PutCall.ofPut(fixedLeg.PayReceive.Receive);
double price = swaptionVolatilities.price(expiry, tenor, putCall, strike, forward, volatility);
double delta = swaptionVolatilities.priceDelta(expiry, tenor, putCall, strike, forward, volatility);
// Backward sweep
PointSensitivityBuilder pvbpDr = SwapPricer.LegPricer.pvbpSensitivity(fixedLeg, ratesProvider);
PointSensitivityBuilder forwardDr = SwapPricer.parRateSensitivity(underlying, ratesProvider);
double sign = swaption.LongShort.sign();
return(pvbpDr.multipliedBy(price * sign * Math.Sign(pvbp)).combinedWith(forwardDr.multipliedBy(delta * Math.Abs(pvbp) * sign)));
}
//-------------------------------------------------------------------------
/// <summary>
/// Calculates the present value sensitivity of the swaption product to the rate curves.
/// <para>
/// The present value sensitivity is computed in a "sticky model parameter" style, i.e. the sensitivity to the
/// curve nodes with the SABR model parameters unchanged. This sensitivity does not include a potential
/// re-calibration of the model parameters to the raw market data.
///
/// </para>
/// </summary>
/// <param name="swaption"> the swaption product </param>
/// <param name="ratesProvider"> the rates provider </param>
/// <param name="swaptionVolatilities"> the volatilities </param>
/// <returns> the point sensitivity to the rate curves </returns>
public virtual PointSensitivityBuilder presentValueSensitivityRatesStickyModel(ResolvedSwaption swaption, RatesProvider ratesProvider, SabrSwaptionVolatilities swaptionVolatilities)
{
validate(swaption, ratesProvider, swaptionVolatilities);
ZonedDateTime expiryDateTime = swaption.Expiry;
double expiry = swaptionVolatilities.relativeTime(expiryDateTime);
ResolvedSwap underlying = swaption.Underlying;
ResolvedSwapLeg fixedLeg = this.fixedLeg(underlying);
if (expiry < 0d)
{ // Option has expired already
return(PointSensitivityBuilder.none());
}
double forward = SwapPricer.parRate(underlying, ratesProvider);
double pvbp = SwapPricer.LegPricer.pvbp(fixedLeg, ratesProvider);
double strike = SwapPricer.LegPricer.couponEquivalent(fixedLeg, ratesProvider, pvbp);
double tenor = swaptionVolatilities.tenor(fixedLeg.StartDate, fixedLeg.EndDate);
double shift = swaptionVolatilities.shift(expiry, tenor);
ValueDerivatives volatilityAdj = swaptionVolatilities.volatilityAdjoint(expiry, tenor, strike, forward);
bool isCall = fixedLeg.PayReceive.Pay;
// Payer at strike is exercise when rate > strike, i.e. call on rate
// Backward sweep
PointSensitivityBuilder pvbpDr = SwapPricer.LegPricer.pvbpSensitivity(fixedLeg, ratesProvider);
PointSensitivityBuilder forwardDr = SwapPricer.parRateSensitivity(underlying, ratesProvider);
double shiftedForward = forward + shift;
double shiftedStrike = strike + shift;
double price = BlackFormulaRepository.price(shiftedForward, shiftedStrike, expiry, volatilityAdj.Value, isCall);
double delta = BlackFormulaRepository.delta(shiftedForward, shiftedStrike, expiry, volatilityAdj.Value, isCall);
double vega = BlackFormulaRepository.vega(shiftedForward, shiftedStrike, expiry, volatilityAdj.Value);
double sign = swaption.LongShort.sign();
return(pvbpDr.multipliedBy(price * sign * Math.Sign(pvbp)).combinedWith(forwardDr.multipliedBy((delta + vega * volatilityAdj.getDerivative(0)) * Math.Abs(pvbp) * sign)));
}
//-------------------------------------------------------------------------
/// <summary>
/// Calculates the present value sensitivity of the swaption to the rate curves.
/// <para>
/// The present value sensitivity is computed in a "sticky strike" style, i.e. the sensitivity to the
/// curve nodes with the volatility at the swaption strike unchanged. This sensitivity does not include a potential
/// change of volatility due to the implicit change of forward rate or moneyness.
///
/// </para>
/// </summary>
/// <param name="swaption"> the swaption </param>
/// <param name="ratesProvider"> the rates provider </param>
/// <param name="swaptionVolatilities"> the volatilities </param>
/// <returns> the point sensitivity to the rate curves </returns>
public virtual PointSensitivityBuilder presentValueSensitivityRatesStickyStrike(ResolvedSwaption swaption, RatesProvider ratesProvider, SwaptionVolatilities swaptionVolatilities)
{
validate(swaption, ratesProvider, swaptionVolatilities);
double expiry = swaptionVolatilities.relativeTime(swaption.Expiry);
ResolvedSwap underlying = swaption.Underlying;
ResolvedSwapLeg fixedLeg = this.fixedLeg(underlying);
if (expiry < 0d)
{ // Option has expired already
return(PointSensitivityBuilder.none());
}
double forward = SwapPricer.parRate(underlying, ratesProvider);
ValueDerivatives annuityDerivative = SwapPricer.LegPricer.annuityCashDerivative(fixedLeg, forward);
double annuityCash = annuityDerivative.Value;
double annuityCashDr = annuityDerivative.getDerivative(0);
LocalDate settlementDate = ((CashSwaptionSettlement)swaption.SwaptionSettlement).SettlementDate;
double discountSettle = ratesProvider.discountFactor(fixedLeg.Currency, settlementDate);
double strike = calculateStrike(fixedLeg);
double tenor = swaptionVolatilities.tenor(fixedLeg.StartDate, fixedLeg.EndDate);
double volatility = swaptionVolatilities.volatility(expiry, tenor, strike, forward);
PutCall putCall = PutCall.ofPut(fixedLeg.PayReceive.Receive);
double price = swaptionVolatilities.price(expiry, tenor, putCall, strike, forward, volatility);
double delta = swaptionVolatilities.priceDelta(expiry, tenor, putCall, strike, forward, volatility);
// Backward sweep
PointSensitivityBuilder forwardSensi = SwapPricer.parRateSensitivity(underlying, ratesProvider);
PointSensitivityBuilder discountSettleSensi = ratesProvider.discountFactors(fixedLeg.Currency).zeroRatePointSensitivity(settlementDate);
double sign = swaption.LongShort.sign();
return(forwardSensi.multipliedBy(sign * discountSettle * (annuityCash * delta + annuityCashDr * price)).combinedWith(discountSettleSensi.multipliedBy(sign * annuityCash * price)));
}
// Compute the accrued interest sensitivity on a given period by approximation
private static PointSensitivityBuilder approximatedInterestSensitivity(OvernightIndexObservation observation, LocalDate endDate, OvernightIndexRates rates)
{
DayCount dayCount = observation.Index.DayCount;
double remainingFixingAccrualFactor = dayCount.yearFraction(observation.EffectiveDate, endDate);
double forwardRate = rates.periodRate(observation, endDate);
PointSensitivityBuilder forwardRateSensitivity = rates.periodRatePointSensitivity(observation, endDate);
double rateExp = 1.0 + forwardRate * remainingFixingAccrualFactor;
forwardRateSensitivity = forwardRateSensitivity.multipliedBy(remainingFixingAccrualFactor / rateExp);
return(forwardRateSensitivity);
}
//-------------------------------------------------------------------------
/// <summary>
/// Computes the present value curve sensitivity by simple forward rate estimation.
/// </summary>
/// <param name="cmsPeriod"> the CMS </param>
/// <param name="provider"> the rates provider </param>
/// <returns> the present value sensitivity </returns>
public virtual PointSensitivityBuilder presentValueSensitivity(CmsPeriod cmsPeriod, RatesProvider provider)
{
Currency ccy = cmsPeriod.Currency;
LocalDate valuationDate = provider.ValuationDate;
if (valuationDate.isAfter(cmsPeriod.PaymentDate))
{
return(PointSensitivityBuilder.none());
}
LocalDate fixingDate = cmsPeriod.FixingDate;
double dfPayment = provider.discountFactor(ccy, cmsPeriod.PaymentDate);
if (!fixingDate.isAfter(valuationDate))
{ // Using fixing
double?fixedRate = provider.timeSeries(cmsPeriod.Index).get(fixingDate);
if (fixedRate.HasValue)
{
double payoff = 0d;
switch (cmsPeriod.CmsPeriodType)
{
case CAPLET:
payoff = Math.Max(fixedRate.Value - cmsPeriod.Strike, 0d);
break;
case FLOORLET:
payoff = Math.Max(cmsPeriod.Strike - fixedRate.Value, 0d);
break;
case COUPON:
payoff = fixedRate.Value;
break;
default:
throw new System.ArgumentException("unsupported CMS type");
}
return(provider.discountFactors(ccy).zeroRatePointSensitivity(cmsPeriod.PaymentDate).multipliedBy(payoff * cmsPeriod.Notional * cmsPeriod.YearFraction));
}
else if (fixingDate.isBefore(valuationDate))
{
throw new System.ArgumentException(Messages.format("Unable to get fixing for {} on date {}, no time-series supplied", cmsPeriod.Index, fixingDate));
}
}
if (!cmsPeriod.CmsPeriodType.Equals(CmsPeriodType.COUPON))
{
throw new System.ArgumentException("Unable to price cap or floor in this pricer");
}
// Using forward
ResolvedSwap swap = cmsPeriod.UnderlyingSwap;
ZeroRateSensitivity dfPaymentdr = provider.discountFactors(ccy).zeroRatePointSensitivity(cmsPeriod.PaymentDate);
double forward = swapPricer.parRate(swap, provider);
PointSensitivityBuilder forwardSensi = swapPricer.parRateSensitivity(swap, provider);
return(forwardSensi.multipliedBy(dfPayment).combinedWith(dfPaymentdr.multipliedBy(forward)).multipliedBy(cmsPeriod.Notional * cmsPeriod.YearFraction));
}
// Calculate the total rate sensitivity.
internal PointSensitivityBuilder calculateRateSensitivity()
{
// call these methods to ensure mutable fixedPeriod variable is updated
pastAccumulation();
valuationDateAccumulation();
// calculate sensitivity
PointSensitivityBuilder combinedPointSensitivity = approximatedForwardAccumulationSensitivity();
PointSensitivityBuilder cutOffAccumulationSensitivity = this.cutOffAccumulationSensitivity();
combinedPointSensitivity = combinedPointSensitivity.combinedWith(cutOffAccumulationSensitivity);
combinedPointSensitivity = combinedPointSensitivity.multipliedBy(1.0d / accrualFactorTotal);
return(combinedPointSensitivity);
}
// Composition - forward part in non-cutoff period; past/valuation date case dealt with in previous methods
internal ObjDoublePair <PointSensitivityBuilder> compositionFactorAndSensitivityNonCutoff()
{
if (!nextFixing.isAfter(lastFixingNonCutoff))
{
OvernightIndexObservation obs = computation.observeOn(nextFixing);
LocalDate startDate = obs.EffectiveDate;
LocalDate endDate = computation.calculateMaturityFromFixing(lastFixingNonCutoff);
double accrualFactor = dayCount.yearFraction(startDate, endDate);
double rate = rates.periodRate(obs, endDate);
PointSensitivityBuilder rateSensitivity = rates.periodRatePointSensitivity(obs, endDate);
rateSensitivity = rateSensitivity.multipliedBy(accrualFactor);
return(ObjDoublePair.of(rateSensitivity, 1.0d + accrualFactor * rate));
}
return(ObjDoublePair.of(PointSensitivityBuilder.none(), 1.0d));
}
private PointSensitivityBuilder rateForwardSensitivity(OvernightAveragedRateComputation computation, OvernightIndexRates rates)
{
OvernightIndex index = computation.Index;
HolidayCalendar calendar = computation.FixingCalendar;
LocalDate startFixingDate = computation.StartDate;
LocalDate endFixingDateP1 = computation.EndDate;
LocalDate endFixingDate = calendar.previous(endFixingDateP1);
LocalDate onRateEndDate = computation.calculateMaturityFromFixing(endFixingDate);
LocalDate onRateStartDate = computation.calculateEffectiveFromFixing(startFixingDate);
LocalDate lastNonCutOffMatDate = onRateEndDate;
int cutoffOffset = computation.RateCutOffDays > 1 ? computation.RateCutOffDays : 1;
PointSensitivityBuilder combinedPointSensitivityBuilder = PointSensitivityBuilder.none();
double accrualFactorTotal = index.DayCount.yearFraction(onRateStartDate, onRateEndDate);
if (cutoffOffset > 1)
{ // Cut-off period
IList <double> noCutOffAccrualFactorList = new List <double>();
LocalDate currentFixingDate = endFixingDateP1;
LocalDate cutOffEffectiveDate;
for (int i = 0; i < cutoffOffset; i++)
{
currentFixingDate = calendar.previous(currentFixingDate);
cutOffEffectiveDate = computation.calculateEffectiveFromFixing(currentFixingDate);
lastNonCutOffMatDate = computation.calculateMaturityFromEffective(cutOffEffectiveDate);
double accrualFactor = index.DayCount.yearFraction(cutOffEffectiveDate, lastNonCutOffMatDate);
noCutOffAccrualFactorList.Add(accrualFactor);
}
OvernightIndexObservation lastIndexObs = computation.observeOn(currentFixingDate);
PointSensitivityBuilder forwardRateCutOffSensitivity = rates.ratePointSensitivity(lastIndexObs);
double totalAccrualFactor = 0.0;
for (int i = 0; i < cutoffOffset - 1; i++)
{
totalAccrualFactor += noCutOffAccrualFactorList[i];
}
forwardRateCutOffSensitivity = forwardRateCutOffSensitivity.multipliedBy(totalAccrualFactor);
combinedPointSensitivityBuilder = combinedPointSensitivityBuilder.combinedWith(forwardRateCutOffSensitivity);
}
// Approximated part
OvernightIndexObservation indexObs = computation.observeOn(onRateStartDate);
PointSensitivityBuilder approximatedInterestAndSensitivity = approximatedInterestSensitivity(indexObs, lastNonCutOffMatDate, rates);
combinedPointSensitivityBuilder = combinedPointSensitivityBuilder.combinedWith(approximatedInterestAndSensitivity);
combinedPointSensitivityBuilder = combinedPointSensitivityBuilder.multipliedBy(1.0 / accrualFactorTotal);
// final rate
return(combinedPointSensitivityBuilder);
}
// Composition - forward part in the cutoff period; past/valuation date case dealt with in previous methods
internal ObjDoublePair <PointSensitivityBuilder> compositionFactorAndSensitivityCutoff()
{
OvernightIndexObservation obs = computation.observeOn(lastFixingNonCutoff);
if (!nextFixing.isAfter(lastFixingNonCutoff))
{
double rate = rates.rate(obs);
double compositionFactor = 1.0d;
double compositionFactorDerivative = 0.0;
for (int i = 0; i < cutoffOffset - 1; i++)
{
compositionFactor *= 1.0d + accrualFactorCutoff[i] * rate;
compositionFactorDerivative += accrualFactorCutoff[i] / (1.0d + accrualFactorCutoff[i] * rate);
}
compositionFactorDerivative *= compositionFactor;
PointSensitivityBuilder rateSensitivity = cutoffOffset <= 1 ? PointSensitivityBuilder.none() : rates.ratePointSensitivity(obs);
rateSensitivity = rateSensitivity.multipliedBy(compositionFactorDerivative);
return(ObjDoublePair.of(rateSensitivity, compositionFactor));
}
return(ObjDoublePair.of(PointSensitivityBuilder.none(), 1.0d));
}
public virtual void test_presentValueSensitivityRatesStickyStrike_parity()
{
CurrencyParameterSensitivities pvSensiRecLong = RATE_PROVIDER.parameterSensitivity(PRICER_SWAPTION.presentValueSensitivityRatesStickyStrike(SWAPTION_REC_LONG, RATE_PROVIDER, VOLS).build());
CurrencyParameterSensitivities pvSensiRecShort = RATE_PROVIDER.parameterSensitivity(PRICER_SWAPTION.presentValueSensitivityRatesStickyStrike(SWAPTION_REC_SHORT, RATE_PROVIDER, VOLS).build());
CurrencyParameterSensitivities pvSensiPayLong = RATE_PROVIDER.parameterSensitivity(PRICER_SWAPTION.presentValueSensitivityRatesStickyStrike(SWAPTION_PAY_LONG, RATE_PROVIDER, VOLS).build());
CurrencyParameterSensitivities pvSensiPayShort = RATE_PROVIDER.parameterSensitivity(PRICER_SWAPTION.presentValueSensitivityRatesStickyStrike(SWAPTION_PAY_SHORT, RATE_PROVIDER, VOLS).build());
assertTrue(pvSensiRecLong.equalWithTolerance(pvSensiRecShort.multipliedBy(-1d), NOTIONAL * TOL));
assertTrue(pvSensiPayLong.equalWithTolerance(pvSensiPayShort.multipliedBy(-1d), NOTIONAL * TOL));
double forward = PRICER_SWAP.parRate(RSWAP_REC, RATE_PROVIDER);
PointSensitivityBuilder forwardSensi = PRICER_SWAP.parRateSensitivity(RSWAP_REC, RATE_PROVIDER);
double annuityCash = PRICER_SWAP.LegPricer.annuityCash(RSWAP_REC.getLegs(SwapLegType.FIXED).get(0), forward);
double annuityCashDeriv = PRICER_SWAP.LegPricer.annuityCashDerivative(RSWAP_REC.getLegs(SwapLegType.FIXED).get(0), forward).getDerivative(0);
double discount = RATE_PROVIDER.discountFactor(USD, SETTLE_DATE);
PointSensitivityBuilder discountSensi = RATE_PROVIDER.discountFactors(USD).zeroRatePointSensitivity(SETTLE_DATE);
PointSensitivities expecedPoint = discountSensi.multipliedBy(annuityCash * (forward - STRIKE)).combinedWith(forwardSensi.multipliedBy(discount * annuityCash + discount * annuityCashDeriv * (forward - STRIKE))).build();
CurrencyParameterSensitivities expected = RATE_PROVIDER.parameterSensitivity(expecedPoint);
assertTrue(expected.equalWithTolerance(pvSensiPayLong.combinedWith(pvSensiRecLong.multipliedBy(-1d)), NOTIONAL * TOL));
assertTrue(expected.equalWithTolerance(pvSensiRecShort.combinedWith(pvSensiPayShort.multipliedBy(-1d)), NOTIONAL * TOL));
}
/// <summary>
/// Calculates the present value sensitivity of the product.
/// <para>
/// The present value sensitivity of the product is the sensitivity of present value to the underlying curves.
///
/// </para>
/// </summary>
/// <param name="cdsIndex"> the product </param>
/// <param name="ratesProvider"> the rates provider </param>
/// <param name="referenceDate"> the reference date </param>
/// <param name="refData"> the reference data </param>
/// <returns> the present value sensitivity </returns>
public virtual PointSensitivityBuilder presentValueSensitivity(ResolvedCdsIndex cdsIndex, CreditRatesProvider ratesProvider, LocalDate referenceDate, ReferenceData refData)
{
if (isExpired(cdsIndex, ratesProvider))
{
return(PointSensitivityBuilder.none());
}
ResolvedCds cds = cdsIndex.toSingleNameCds();
LocalDate stepinDate = cds.StepinDateOffset.adjust(ratesProvider.ValuationDate, refData);
LocalDate effectiveStartDate = cds.calculateEffectiveStartDate(stepinDate);
double recoveryRate = underlyingPricer.recoveryRate(cds, ratesProvider);
Triple <CreditDiscountFactors, LegalEntitySurvivalProbabilities, double> rates = reduceDiscountFactors(cds, ratesProvider);
double signedNotional = cds.BuySell.normalize(cds.Notional);
PointSensitivityBuilder protectionLegSensi = underlyingPricer.protectionLegSensitivity(cds, rates.First, rates.Second, referenceDate, effectiveStartDate, recoveryRate);
protectionLegSensi = protectionLegSensi.multipliedBy(signedNotional * rates.Third);
PointSensitivityBuilder riskyAnnuitySensi = underlyingPricer.riskyAnnuitySensitivity(cds, rates.First, rates.Second, referenceDate, stepinDate, effectiveStartDate);
riskyAnnuitySensi = riskyAnnuitySensi.multipliedBy(-cds.FixedRate * signedNotional * rates.Third);
return(protectionLegSensi.combinedWith(riskyAnnuitySensi));
}
//-------------------------------------------------------------------------
/// <summary>
/// Calculates the present value sensitivity of the swaption product.
/// <para>
/// The present value sensitivity of the product is the sensitivity of the present value to
/// the underlying curves.
///
/// </para>
/// </summary>
/// <param name="swaption"> the product </param>
/// <param name="ratesProvider"> the rates provider </param>
/// <param name="hwProvider"> the Hull-White model parameter provider </param>
/// <returns> the point sensitivity to the rate curves </returns>
public virtual PointSensitivityBuilder presentValueSensitivityRates(ResolvedSwaption swaption, RatesProvider ratesProvider, HullWhiteOneFactorPiecewiseConstantParametersProvider hwProvider)
{
validate(swaption, ratesProvider, hwProvider);
ResolvedSwap swap = swaption.Underlying;
LocalDate expiryDate = swaption.ExpiryDate;
if (expiryDate.isBefore(ratesProvider.ValuationDate))
{ // Option has expired already
return(PointSensitivityBuilder.none());
}
ImmutableMap <Payment, PointSensitivityBuilder> cashFlowEquivSensi = CashFlowEquivalentCalculator.cashFlowEquivalentAndSensitivitySwap(swap, ratesProvider);
ImmutableList <Payment> list = cashFlowEquivSensi.Keys.asList();
ImmutableList <PointSensitivityBuilder> listSensi = cashFlowEquivSensi.values().asList();
int nPayments = list.size();
double[] alpha = new double[nPayments];
double[] discountedCashFlow = new double[nPayments];
for (int loopcf = 0; loopcf < nPayments; loopcf++)
{
Payment payment = list.get(loopcf);
alpha[loopcf] = hwProvider.alpha(ratesProvider.ValuationDate, expiryDate, expiryDate, payment.Date);
discountedCashFlow[loopcf] = paymentPricer.presentValueAmount(payment, ratesProvider);
}
double omega = (swap.getLegs(SwapLegType.FIXED).get(0).PayReceive.Pay ? -1d : 1d);
double kappa = computeKappa(hwProvider, discountedCashFlow, alpha, omega);
PointSensitivityBuilder point = PointSensitivityBuilder.none();
for (int loopcf = 0; loopcf < nPayments; loopcf++)
{
Payment payment = list.get(loopcf);
double cdf = NORMAL.getCDF(omega * (kappa + alpha[loopcf]));
point = point.combinedWith(paymentPricer.presentValueSensitivity(payment, ratesProvider).multipliedBy(cdf));
if (!listSensi.get(loopcf).Equals(PointSensitivityBuilder.none()))
{
point = point.combinedWith(listSensi.get(loopcf).multipliedBy(cdf * ratesProvider.discountFactor(payment.Currency, payment.Date)));
}
}
return(swaption.LongShort.Long ? point : point.multipliedBy(-1d));
}
internal virtual PointSensitivityBuilder riskyAnnuitySensitivity(ResolvedCds cds, CreditDiscountFactors discountFactors, LegalEntitySurvivalProbabilities survivalProbabilities, LocalDate referenceDate, LocalDate stepinDate, LocalDate effectiveStartDate)
{
double pv = 0d;
PointSensitivityBuilder pvSensi = PointSensitivityBuilder.none();
foreach (CreditCouponPaymentPeriod coupon in cds.PaymentPeriods)
{
if (stepinDate.isBefore(coupon.EndDate))
{
double q = survivalProbabilities.survivalProbability(coupon.EffectiveEndDate);
PointSensitivityBuilder qSensi = survivalProbabilities.zeroRatePointSensitivity(coupon.EffectiveEndDate);
double p = discountFactors.discountFactor(coupon.PaymentDate);
PointSensitivityBuilder pSensi = discountFactors.zeroRatePointSensitivity(coupon.PaymentDate);
pv += coupon.YearFraction * p * q;
pvSensi = pvSensi.combinedWith(pSensi.multipliedBy(coupon.YearFraction * q).combinedWith(qSensi.multipliedBy(coupon.YearFraction * p)));
}
}
if (cds.PaymentOnDefault.AccruedInterest)
{
// This is needed so that the code is consistent with ISDA C when the Markit `fix' is used.
LocalDate start = cds.PaymentPeriods.size() == 1 ? effectiveStartDate : cds.AccrualStartDate;
DoubleArray integrationSchedule = DoublesScheduleGenerator.getIntegrationsPoints(discountFactors.relativeYearFraction(start), discountFactors.relativeYearFraction(cds.ProtectionEndDate), discountFactors.ParameterKeys, survivalProbabilities.ParameterKeys);
foreach (CreditCouponPaymentPeriod coupon in cds.PaymentPeriods)
{
Pair <double, PointSensitivityBuilder> pvAndSensi = singlePeriodAccrualOnDefaultSensitivity(coupon, effectiveStartDate, integrationSchedule, discountFactors, survivalProbabilities);
pv += pvAndSensi.First;
pvSensi = pvSensi.combinedWith(pvAndSensi.Second);
}
}
double df = discountFactors.discountFactor(referenceDate);
PointSensitivityBuilder dfSensi = discountFactors.zeroRatePointSensitivity(referenceDate).multipliedBy(-pv / (df * df));
pvSensi = pvSensi.multipliedBy(1d / df);
return(dfSensi.combinedWith(pvSensi));
}
/// <summary>
/// Calculates the par rate curve sensitivity for a swap with a fixed leg.
/// <para>
/// The par rate is the common rate on all payments of the fixed leg for which the total swap present value is 0.
/// </para>
/// <para>
/// At least one leg must be a fixed leg. The par rate will be computed with respect to the first fixed leg.
/// All the payments in that leg should be fixed payments with a unique accrual period (no compounding) and no FX reset.
///
/// </para>
/// </summary>
/// <param name="swap"> the product </param>
/// <param name="provider"> the rates provider </param>
/// <returns> the par rate curve sensitivity of the swap product </returns>
public virtual PointSensitivityBuilder parRateSensitivity(ResolvedSwap swap, RatesProvider provider)
{
ResolvedSwapLeg fixedLeg = this.fixedLeg(swap);
Currency ccyFixedLeg = fixedLeg.Currency;
// other payments (not fixed leg coupons) converted in fixed leg currency
double otherLegsConvertedPv = 0.0;
foreach (ResolvedSwapLeg leg in swap.Legs)
{
if (leg != fixedLeg)
{
double pvLocal = legPricer.presentValueInternal(leg, provider);
otherLegsConvertedPv += (pvLocal * provider.fxRate(leg.Currency, ccyFixedLeg));
}
}
double fixedLegEventsPv = legPricer.presentValueEventsInternal(fixedLeg, provider);
double pvbpFixedLeg = legPricer.pvbp(fixedLeg, provider);
// Backward sweep
double otherLegsConvertedPvBar = -1.0d / pvbpFixedLeg;
double fixedLegEventsPvBar = -1.0d / pvbpFixedLeg;
double pvbpFixedLegBar = (otherLegsConvertedPv + fixedLegEventsPv) / (pvbpFixedLeg * pvbpFixedLeg);
PointSensitivityBuilder pvbpFixedLegDr = legPricer.pvbpSensitivity(fixedLeg, provider);
PointSensitivityBuilder fixedLegEventsPvDr = legPricer.presentValueSensitivityEventsInternal(fixedLeg, provider);
PointSensitivityBuilder otherLegsConvertedPvDr = PointSensitivityBuilder.none();
foreach (ResolvedSwapLeg leg in swap.Legs)
{
if (leg != fixedLeg)
{
PointSensitivityBuilder pvLegDr = legPricer.presentValueSensitivity(leg, provider).multipliedBy(provider.fxRate(leg.Currency, ccyFixedLeg));
otherLegsConvertedPvDr = otherLegsConvertedPvDr.combinedWith(pvLegDr);
}
}
otherLegsConvertedPvDr = otherLegsConvertedPvDr.withCurrency(ccyFixedLeg);
return(pvbpFixedLegDr.multipliedBy(pvbpFixedLegBar).combinedWith(fixedLegEventsPvDr.multipliedBy(fixedLegEventsPvBar)).combinedWith(otherLegsConvertedPvDr.multipliedBy(otherLegsConvertedPvBar)));
}
//-------------------------------------------------------------------------
public virtual void test_multipliedBy()
{
PointSensitivityBuilder @base = PointSensitivityBuilder.none();
assertSame(@base.multipliedBy(2.0), @base); // no effect
}
