/**
  * Tests present value in the region where there is extrapolation. Test a hard-coded value. Tests
  * long/short parity. Test payer/receiver/swap parity.
  */
 @Test
 public void testPresentValueExtra() {
   final YieldCurveBundle curves = TestsDataSetsSABR.createCurves1();
   final SABRInterestRateParameters sabrParameter = TestsDataSetsSABR.createSABR1();
   final SABRInterestRateDataBundle sabrBundle =
       new SABRInterestRateDataBundle(sabrParameter, curves);
   final double highStrike = 0.10;
   final SwapFixedIborDefinition swapDefinitionPayerHighStrike =
       SwapFixedIborDefinition.from(
           SETTLEMENT_DATE, CMS_INDEX, NOTIONAL, highStrike, FIXED_IS_PAYER);
   final SwapFixedIborDefinition swapDefinitionReceiverHighStrike =
       SwapFixedIborDefinition.from(
           SETTLEMENT_DATE, CMS_INDEX, NOTIONAL, highStrike, !FIXED_IS_PAYER);
   final SwaptionCashFixedIborDefinition swaptionDefinitionLongPayerHighStrike =
       SwaptionCashFixedIborDefinition.from(EXPIRY_DATE, swapDefinitionPayerHighStrike, IS_LONG);
   final SwaptionCashFixedIborDefinition swaptionDefinitionShortPayerHighStrike =
       SwaptionCashFixedIborDefinition.from(EXPIRY_DATE, swapDefinitionPayerHighStrike, !IS_LONG);
   final SwaptionCashFixedIborDefinition swaptionDefinitionLongReceiverHighStrike =
       SwaptionCashFixedIborDefinition.from(
           EXPIRY_DATE, swapDefinitionReceiverHighStrike, IS_LONG);
   final SwaptionCashFixedIbor swaptionLongPayerHighStrike =
       swaptionDefinitionLongPayerHighStrike.toDerivative(REFERENCE_DATE, CURVES_NAME);
   final SwaptionCashFixedIbor swaptionShortPayerHighStrike =
       swaptionDefinitionShortPayerHighStrike.toDerivative(REFERENCE_DATE, CURVES_NAME);
   final SwaptionCashFixedIbor swaptionLongReceiverHighStrike =
       swaptionDefinitionLongReceiverHighStrike.toDerivative(REFERENCE_DATE, CURVES_NAME);
   final SwaptionCashFixedIborSABRExtrapolationRightMethod method =
       new SwaptionCashFixedIborSABRExtrapolationRightMethod(CUT_OFF_STRIKE, MU);
   final double priceLongPayer = method.presentValue(swaptionLongPayerHighStrike, sabrBundle);
   final double priceShortPayer = method.presentValue(swaptionShortPayerHighStrike, sabrBundle);
   final double priceLongReceiver =
       method.presentValue(swaptionLongReceiverHighStrike, sabrBundle);
   final double priceLongPayerExpected = 557829.033; // Value from previous run
   final double priceLongReceiverExpected = 20759354.082; // Value from previous run
   assertEquals(
       "Swaption cash SABR extrapolation: fixed value",
       priceLongPayerExpected,
       priceLongPayer,
       1E-2);
   assertEquals(
       "Swaption cash SABR extrapolation: fixed value",
       priceLongReceiverExpected,
       priceLongReceiver,
       1E-2);
   assertEquals(
       "Swaption cash SABR extrapolation: long/short parity",
       priceLongPayer,
       -priceShortPayer,
       1E-2);
 }
 /**
  * Cap/floor CMS builder. The fixing date is computed from the start accrual date with the Ibor
  * index spot lag. The underlying swap is computed from that date and the CMS index.
  *
  * @param paymentDate Coupon payment date.
  * @param accrualStartDate Start date of the accrual period.
  * @param accrualEndDate End date of the accrual period.
  * @param accrualFactor Accrual factor of the accrual period.
  * @param notional Coupon notional.
  * @param cmsIndex The CMS index associated to the cap/floor.
  * @param strike The strike
  * @param isCap The cap (true) /floor (false) flag.
  * @return The CMS cap/floor.
  */
 public static CapFloorCMSDefinition from(
     final ZonedDateTime paymentDate,
     final ZonedDateTime accrualStartDate,
     final ZonedDateTime accrualEndDate,
     final double accrualFactor,
     final double notional,
     final CMSIndex cmsIndex,
     final double strike,
     final boolean isCap) {
   ZonedDateTime fixingDate =
       ScheduleCalculator.getAdjustedDate(
           accrualStartDate,
           cmsIndex.getIborIndex().getBusinessDayConvention(),
           cmsIndex.getIborIndex().getCalendar(),
           -cmsIndex.getIborIndex().getSettlementDays());
   // Implementation comment: the underlying swap is used for forward. The notional, rate and payer
   // flag are irrelevant.
   final SwapFixedIborDefinition underlyingSwap =
       SwapFixedIborDefinition.from(accrualStartDate, cmsIndex, 1.0, 1.0, true);
   return from(
       paymentDate,
       accrualStartDate,
       accrualEndDate,
       accrualFactor,
       notional,
       fixingDate,
       underlyingSwap,
       cmsIndex,
       strike,
       isCap);
 }
/** Tests related to the pricing of physical delivery swaption in G2++ model. */
public class SwaptionPhysicalFixedIborG2ppMethodTest {
  // Swaption 5Yx5Y
  private static final Currency CUR = Currency.USD;
  private static final Calendar CALENDAR = new MondayToFridayCalendar("A");
  private static final BusinessDayConvention BUSINESS_DAY =
      BusinessDayConventionFactory.INSTANCE.getBusinessDayConvention("Modified Following");
  private static final boolean IS_EOM = true;
  private static final int SETTLEMENT_DAYS = 2;
  private static final Period IBOR_TENOR = Period.ofMonths(3);
  private static final DayCount IBOR_DAY_COUNT = DayCountFactory.INSTANCE.getDayCount("Actual/360");
  private static final IborIndex IBOR_INDEX =
      new IborIndex(
          CUR, IBOR_TENOR, SETTLEMENT_DAYS, CALENDAR, IBOR_DAY_COUNT, BUSINESS_DAY, IS_EOM);
  private static final int SWAP_TENOR_YEAR = 5;
  private static final Period SWAP_TENOR = Period.ofYears(SWAP_TENOR_YEAR);
  private static final Period FIXED_PAYMENT_PERIOD = Period.ofMonths(6);
  private static final DayCount FIXED_DAY_COUNT = DayCountFactory.INSTANCE.getDayCount("30/360");
  private static final CMSIndex CMS_INDEX =
      new CMSIndex(FIXED_PAYMENT_PERIOD, FIXED_DAY_COUNT, IBOR_INDEX, SWAP_TENOR);
  private static final ZonedDateTime EXPIRY_DATE = DateUtils.getUTCDate(2016, 7, 7);
  private static final ZonedDateTime SETTLEMENT_DATE =
      ScheduleCalculator.getAdjustedDate(EXPIRY_DATE, CALENDAR, SETTLEMENT_DAYS);
  private static final double NOTIONAL = 100000000; // 100m
  private static final double RATE = 0.0325;
  private static final boolean FIXED_IS_PAYER = true;
  private static final SwapFixedIborDefinition SWAP_PAYER_DEFINITION =
      SwapFixedIborDefinition.from(SETTLEMENT_DATE, CMS_INDEX, NOTIONAL, RATE, FIXED_IS_PAYER);
  private static final SwapFixedIborDefinition SWAP_RECEIVER_DEFINITION =
      SwapFixedIborDefinition.from(SETTLEMENT_DATE, CMS_INDEX, NOTIONAL, RATE, !FIXED_IS_PAYER);
  private static final boolean IS_LONG = true;
  private static final SwaptionPhysicalFixedIborDefinition SWAPTION_PAYER_LONG_DEFINITION =
      SwaptionPhysicalFixedIborDefinition.from(EXPIRY_DATE, SWAP_PAYER_DEFINITION, IS_LONG);
  private static final SwaptionPhysicalFixedIborDefinition SWAPTION_RECEIVER_LONG_DEFINITION =
      SwaptionPhysicalFixedIborDefinition.from(EXPIRY_DATE, SWAP_RECEIVER_DEFINITION, IS_LONG);
  private static final SwaptionPhysicalFixedIborDefinition SWAPTION_PAYER_SHORT_DEFINITION =
      SwaptionPhysicalFixedIborDefinition.from(EXPIRY_DATE, SWAP_PAYER_DEFINITION, !IS_LONG);
  private static final SwaptionPhysicalFixedIborDefinition SWAPTION_RECEIVER_SHORT_DEFINITION =
      SwaptionPhysicalFixedIborDefinition.from(EXPIRY_DATE, SWAP_RECEIVER_DEFINITION, !IS_LONG);
  // to derivatives
  private static final ZonedDateTime REFERENCE_DATE = DateUtils.getUTCDate(2011, 7, 7);
  private static final String FUNDING_CURVE_NAME = "Funding";
  private static final String FORWARD_CURVE_NAME = "Forward";
  private static final String[] CURVES_NAME = {FUNDING_CURVE_NAME, FORWARD_CURVE_NAME};
  private static final YieldCurveBundle CURVES = TestsDataSets.createCurves1();
  private static final FixedCouponSwap<Coupon> SWAP_RECEIVER =
      SWAP_RECEIVER_DEFINITION.toDerivative(REFERENCE_DATE, CURVES_NAME);
  private static final SwaptionPhysicalFixedIbor SWAPTION_PAYER_LONG =
      SWAPTION_PAYER_LONG_DEFINITION.toDerivative(REFERENCE_DATE, CURVES_NAME);
  private static final SwaptionPhysicalFixedIbor SWAPTION_RECEIVER_LONG =
      SWAPTION_RECEIVER_LONG_DEFINITION.toDerivative(REFERENCE_DATE, CURVES_NAME);
  private static final SwaptionPhysicalFixedIbor SWAPTION_PAYER_SHORT =
      SWAPTION_PAYER_SHORT_DEFINITION.toDerivative(REFERENCE_DATE, CURVES_NAME);
  private static final SwaptionPhysicalFixedIbor SWAPTION_RECEIVER_SHORT =
      SWAPTION_RECEIVER_SHORT_DEFINITION.toDerivative(REFERENCE_DATE, CURVES_NAME);
  // Calculator
  private static final SwaptionPhysicalFixedIborG2ppApproximationMethod METHOD_G2PP_APPROXIMATION =
      new SwaptionPhysicalFixedIborG2ppApproximationMethod();
  private static final SwaptionPhysicalFixedIborG2ppNumericalIntegrationMethod METHOD_G2PP_NI =
      new SwaptionPhysicalFixedIborG2ppNumericalIntegrationMethod();
  private static final G2ppPiecewiseConstantParameters PARAMETERS_G2PP =
      G2ppTestsDataSet.createG2ppParameters();
  private static final G2ppPiecewiseConstantDataBundle BUNDLE_G2PP =
      new G2ppPiecewiseConstantDataBundle(PARAMETERS_G2PP, CURVES);
  private static final PresentValueCalculator PVC = PresentValueCalculator.getInstance();

  @Test(enabled = false)
  /**
   * Test the present value vs a external system. "enabled = false" for the standard testing: the
   * external system is using a TimeCalculator with ACT/365.
   */
  public void presentValueExternal() {
    G2ppPiecewiseConstantParameters parametersCst = G2ppTestsDataSet.createG2ppCstParameters();
    final YieldAndDiscountCurve curve5 = new YieldCurve(ConstantDoublesCurve.from(0.05));
    final YieldCurveBundle curves = new YieldCurveBundle();
    curves.setCurve(FUNDING_CURVE_NAME, curve5);
    curves.setCurve(FORWARD_CURVE_NAME, curve5);
    G2ppPiecewiseConstantDataBundle bundleCst =
        new G2ppPiecewiseConstantDataBundle(parametersCst, curves);
    CurrencyAmount pv = METHOD_G2PP_APPROXIMATION.presentValue(SWAPTION_PAYER_LONG, bundleCst);
    double pvExternal = 6885626.28245924; // ! TimeCalculator with ACT/365
    assertEquals(
        "Swaption physical - G2++ - present value - external system",
        pvExternal,
        pv.getAmount(),
        1E-2);
  }

  @Test(enabled = true)
  /** Test the present value vs a hard-coded value. */
  public void presentValue() {
    CurrencyAmount pv = METHOD_G2PP_APPROXIMATION.presentValue(SWAPTION_PAYER_LONG, BUNDLE_G2PP);
    double pvExpected = 4893110.87;
    assertEquals(
        "Swaption physical - G2++ - present value - hard coded value",
        pvExpected,
        pv.getAmount(),
        1E-2);
  }

  @Test
  /** Tests long/short parity. */
  public void longShortParity() {
    CurrencyAmount pvPayerLong =
        METHOD_G2PP_APPROXIMATION.presentValue(SWAPTION_PAYER_LONG, BUNDLE_G2PP);
    CurrencyAmount pvPayerShort =
        METHOD_G2PP_APPROXIMATION.presentValue(SWAPTION_PAYER_SHORT, BUNDLE_G2PP);
    assertEquals(
        "Swaption physical - G2++ - present value - long/short parity",
        pvPayerLong.getAmount(),
        -pvPayerShort.getAmount(),
        1E-2);
    CurrencyAmount pvReceiverLong =
        METHOD_G2PP_APPROXIMATION.presentValue(SWAPTION_RECEIVER_LONG, BUNDLE_G2PP);
    CurrencyAmount pvReceiverShort =
        METHOD_G2PP_APPROXIMATION.presentValue(SWAPTION_RECEIVER_SHORT, BUNDLE_G2PP);
    assertEquals(
        "Swaption physical - G2++ - present value - long/short parity",
        pvReceiverLong.getAmount(),
        -pvReceiverShort.getAmount(),
        1E-2);
  }

  @Test
  /** Tests payer/receiver/swap parity. */
  public void payerReceiverParity() {
    CurrencyAmount pvReceiverLong =
        METHOD_G2PP_APPROXIMATION.presentValue(SWAPTION_RECEIVER_LONG, BUNDLE_G2PP);
    CurrencyAmount pvPayerShort =
        METHOD_G2PP_APPROXIMATION.presentValue(SWAPTION_PAYER_SHORT, BUNDLE_G2PP);
    double pvSwap = PVC.visit(SWAP_RECEIVER, CURVES);
    assertEquals(
        "Swaption physical - G2++ - present value - payer/receiver/swap parity",
        pvReceiverLong.getAmount() + pvPayerShort.getAmount(),
        pvSwap,
        1E-2);
  }

  @Test
  /** Test the present value by approximation vs by numerical integration. */
  public void approximationNumericalIntegration() {
    CurrencyAmount pvApproximation =
        METHOD_G2PP_APPROXIMATION.presentValue(SWAPTION_PAYER_LONG, BUNDLE_G2PP);
    CurrencyAmount pvNI = METHOD_G2PP_NI.presentValue(SWAPTION_PAYER_LONG, BUNDLE_G2PP);
    assertEquals(
        "Swaption physical - G2++ - present value - approximation vs Numerical integration",
        pvApproximation.getAmount(),
        pvNI.getAmount(),
        2.0E+3);
  }

  @Test(enabled = false)
  /** Tests of performance. "enabled = false" for the standard testing. */
  public void performance() {
    long startTime, endTime;
    final int nbTest = 100;
    CurrencyAmount pvPayerLongApproximation = CurrencyAmount.of(CUR, 0.0);
    CurrencyAmount pvPayerLongNI = CurrencyAmount.of(CUR, 0.0);
    startTime = System.currentTimeMillis();
    for (int looptest = 0; looptest < nbTest; looptest++) {
      pvPayerLongApproximation =
          METHOD_G2PP_APPROXIMATION.presentValue(SWAPTION_PAYER_LONG, BUNDLE_G2PP);
    }
    endTime = System.currentTimeMillis();
    System.out.println(
        nbTest + " pv swaption G2++ approximation method: " + (endTime - startTime) + " ms");
    // Performance note: G2++ price: 24-Aug-11: On Mac Pro 3.2 GHz Quad-Core Intel Xeon: 175 ms for
    // 10000 swaptions.
    startTime = System.currentTimeMillis();
    for (int looptest = 0; looptest < nbTest; looptest++) {
      pvPayerLongNI = METHOD_G2PP_NI.presentValue(SWAPTION_PAYER_LONG, BUNDLE_G2PP);
    }
    endTime = System.currentTimeMillis();
    System.out.println(
        nbTest
            + " pv swaption G2++ numerical integration method: "
            + (endTime - startTime)
            + " ms");
    // Performance note: G2++ price: 24-Aug-11: On Mac Pro 3.2 GHz Quad-Core Intel Xeon: 1075 ms for
    // 100 swaptions.

    System.out.println("G2++ approximation - present value: " + pvPayerLongApproximation);
    System.out.println("G2++ numerical integration - present value: " + pvPayerLongNI);
  }
}
/** Tests related to the construction of CapFloorCMSSpread. */
public class CapFloorCMSSpreadTest {

  // Swaps
  private static final Currency CUR = Currency.USD;
  private static final Calendar CALENDAR = new MondayToFridayCalendar("A");
  private static final BusinessDayConvention BUSINESS_DAY =
      BusinessDayConventionFactory.INSTANCE.getBusinessDayConvention("Modified Following");
  private static final boolean IS_EOM = true;
  private static final ZonedDateTime SETTLEMENT_DATE = DateUtils.getUTCDate(2011, 3, 17);
  private static final Period FIXED_PAYMENT_PERIOD = Period.ofMonths(6);
  private static final DayCount FIXED_DAY_COUNT = DayCountFactory.INSTANCE.getDayCount("30/360");
  private static final boolean FIXED_IS_PAYER = true; // Irrelevant for the underlying
  private static final double RATE = 0.0; // Irrelevant for the underlying
  private static final Period INDEX_TENOR = Period.ofMonths(3);
  private static final int SETTLEMENT_DAYS = 2;
  private static final DayCount DAY_COUNT = DayCountFactory.INSTANCE.getDayCount("Actual/360");
  private static final IborIndex IBOR_INDEX =
      new IborIndex(CUR, INDEX_TENOR, SETTLEMENT_DAYS, CALENDAR, DAY_COUNT, BUSINESS_DAY, IS_EOM);
  // Swap 10Y
  private static final Period ANNUITY_TENOR_1 = Period.ofYears(10);
  private static final IndexSwap CMS_INDEX_1 =
      new IndexSwap(FIXED_PAYMENT_PERIOD, FIXED_DAY_COUNT, IBOR_INDEX, ANNUITY_TENOR_1);
  private static final SwapFixedIborDefinition SWAP_DEFINITION_1 =
      SwapFixedIborDefinition.from(SETTLEMENT_DATE, CMS_INDEX_1, 1.0, RATE, FIXED_IS_PAYER);
  // Swap 2Y
  private static final Period ANNUITY_TENOR_2 = Period.ofYears(2);
  private static final IndexSwap CMS_INDEX_2 =
      new IndexSwap(FIXED_PAYMENT_PERIOD, FIXED_DAY_COUNT, IBOR_INDEX, ANNUITY_TENOR_2);
  private static final SwapFixedIborDefinition SWAP_DEFINITION_2 =
      SwapFixedIborDefinition.from(SETTLEMENT_DATE, CMS_INDEX_2, 1.0, RATE, FIXED_IS_PAYER);
  // CMS spread coupon
  private static final double NOTIONAL = 10000000;
  private static final ZonedDateTime PAYMENT_DATE = DateUtils.getUTCDate(2011, 4, 6);
  private static final ZonedDateTime FIXING_DATE = DateUtils.getUTCDate(2010, 12, 30);
  private static final ZonedDateTime ACCRUAL_START_DATE = DateUtils.getUTCDate(2011, 1, 5);
  private static final ZonedDateTime ACCRUAL_END_DATE = DateUtils.getUTCDate(2011, 4, 5);
  private static final DayCount PAYMENT_DAY_COUNT =
      DayCountFactory.INSTANCE.getDayCount("Actual/360");
  private static final double PAYMENT_ACCRUAL_FACTOR =
      PAYMENT_DAY_COUNT.getDayCountFraction(ACCRUAL_START_DATE, ACCRUAL_END_DATE);
  private static final double STRIKE = 0.0050; // 50 bps
  private static final boolean IS_CAP = true;
  // to derivatives
  private static final ZonedDateTime REFERENCE_DATE = DateUtils.getUTCDate(2010, 8, 18);
  private static final String FUNDING_CURVE_NAME = "Funding";
  private static final String FORWARD_CURVE_1_NAME = "Forward 1";
  //  private static final String FORWARD_CURVE_2_NAME = "Forward 2";
  private static final String[] CURVES_2_NAME = {FUNDING_CURVE_NAME, FORWARD_CURVE_1_NAME};
  //  private static final String[] CURVES_3_NAME = {FUNDING_CURVE_NAME, FORWARD_CURVE_1_NAME,
  // FORWARD_CURVE_2_NAME};
  private static final FixedCouponSwap<? extends Payment> SWAP_1 =
      SWAP_DEFINITION_1.toDerivative(REFERENCE_DATE, CURVES_2_NAME);
  private static final FixedCouponSwap<? extends Payment> SWAP_2 =
      SWAP_DEFINITION_2.toDerivative(REFERENCE_DATE, CURVES_2_NAME);
  private static final DayCount ACT_ACT =
      DayCountFactory.INSTANCE.getDayCount("Actual/Actual ISDA");
  private static final ZonedDateTime REFERENCE_DATE_ZONED =
      ZonedDateTime.of(LocalDateTime.ofMidnight(REFERENCE_DATE), TimeZone.UTC);
  private static final double PAYMENT_TIME =
      ACT_ACT.getDayCountFraction(REFERENCE_DATE_ZONED, PAYMENT_DATE);
  private static final double FIXING_TIME =
      ACT_ACT.getDayCountFraction(REFERENCE_DATE_ZONED, FIXING_DATE);
  private static final double SETTLEMENT_TIME =
      ACT_ACT.getDayCountFraction(
          REFERENCE_DATE_ZONED,
          SWAP_DEFINITION_1.getFixedLeg().getNthPayment(0).getAccrualStartDate());

  private static final CapFloorCMSSpread CMS_SPREAD =
      new CapFloorCMSSpread(
          CUR,
          PAYMENT_TIME,
          PAYMENT_ACCRUAL_FACTOR,
          NOTIONAL,
          FIXING_TIME,
          SWAP_1,
          CMS_INDEX_1,
          SWAP_2,
          CMS_INDEX_2,
          SETTLEMENT_TIME,
          STRIKE,
          IS_CAP,
          FUNDING_CURVE_NAME);

  @Test
  public void testGetter() {
    assertEquals(SWAP_1, CMS_SPREAD.getUnderlyingSwap1());
    assertEquals(CMS_INDEX_1, CMS_SPREAD.getCmsIndex1());
    assertEquals(SWAP_2, CMS_SPREAD.getUnderlyingSwap2());
    assertEquals(CMS_INDEX_2, CMS_SPREAD.getCmsIndex2());
    assertEquals(STRIKE, CMS_SPREAD.getStrike(), 1E-10);
    assertEquals(IS_CAP, CMS_SPREAD.isCap());
  }

  @Test
  public void testEqualHash() {
    final CapFloorCMSSpread newCMSSpread =
        new CapFloorCMSSpread(
            CUR,
            PAYMENT_TIME,
            PAYMENT_ACCRUAL_FACTOR,
            NOTIONAL,
            FIXING_TIME,
            SWAP_1,
            CMS_INDEX_1,
            SWAP_2,
            CMS_INDEX_2,
            SETTLEMENT_TIME,
            STRIKE,
            IS_CAP,
            FUNDING_CURVE_NAME);
    assertEquals(newCMSSpread.equals(CMS_SPREAD), true);
    assertEquals(newCMSSpread.hashCode() == CMS_SPREAD.hashCode(), true);
    final Currency newCur = Currency.EUR;
    CapFloorCMSSpread modifiedCMSSpread;
    modifiedCMSSpread =
        new CapFloorCMSSpread(
            newCur,
            PAYMENT_TIME,
            PAYMENT_ACCRUAL_FACTOR,
            NOTIONAL,
            FIXING_TIME,
            SWAP_1,
            CMS_INDEX_1,
            SWAP_2,
            CMS_INDEX_2,
            SETTLEMENT_TIME,
            STRIKE,
            IS_CAP,
            FUNDING_CURVE_NAME);
    assertEquals(modifiedCMSSpread.equals(CMS_SPREAD), false);
    modifiedCMSSpread =
        new CapFloorCMSSpread(
            CUR,
            PAYMENT_TIME + 1.0,
            PAYMENT_ACCRUAL_FACTOR,
            NOTIONAL,
            FIXING_TIME,
            SWAP_1,
            CMS_INDEX_1,
            SWAP_2,
            CMS_INDEX_2,
            SETTLEMENT_TIME,
            STRIKE,
            IS_CAP,
            FUNDING_CURVE_NAME);
    assertEquals(modifiedCMSSpread.equals(CMS_SPREAD), false);
    modifiedCMSSpread =
        new CapFloorCMSSpread(
            CUR,
            PAYMENT_TIME,
            PAYMENT_ACCRUAL_FACTOR + 1.0,
            NOTIONAL,
            FIXING_TIME,
            SWAP_1,
            CMS_INDEX_1,
            SWAP_2,
            CMS_INDEX_2,
            SETTLEMENT_TIME,
            STRIKE,
            IS_CAP,
            FUNDING_CURVE_NAME);
    assertEquals(modifiedCMSSpread.equals(CMS_SPREAD), false);
    modifiedCMSSpread =
        new CapFloorCMSSpread(
            CUR,
            PAYMENT_TIME,
            PAYMENT_ACCRUAL_FACTOR,
            NOTIONAL + 1.0,
            FIXING_TIME,
            SWAP_1,
            CMS_INDEX_1,
            SWAP_2,
            CMS_INDEX_2,
            SETTLEMENT_TIME,
            STRIKE,
            IS_CAP,
            FUNDING_CURVE_NAME);
    assertEquals(modifiedCMSSpread.equals(CMS_SPREAD), false);
    modifiedCMSSpread =
        new CapFloorCMSSpread(
            CUR,
            PAYMENT_TIME,
            PAYMENT_ACCRUAL_FACTOR,
            NOTIONAL,
            FIXING_TIME + 1.0,
            SWAP_1,
            CMS_INDEX_1,
            SWAP_2,
            CMS_INDEX_2,
            SETTLEMENT_TIME,
            STRIKE,
            IS_CAP,
            FUNDING_CURVE_NAME);
    assertEquals(modifiedCMSSpread.equals(CMS_SPREAD), false);
    modifiedCMSSpread =
        new CapFloorCMSSpread(
            CUR,
            PAYMENT_TIME,
            PAYMENT_ACCRUAL_FACTOR,
            NOTIONAL,
            FIXING_TIME,
            SWAP_1,
            CMS_INDEX_1,
            SWAP_2,
            CMS_INDEX_2,
            SETTLEMENT_TIME + 1.0,
            STRIKE,
            IS_CAP,
            FUNDING_CURVE_NAME);
    assertEquals(modifiedCMSSpread.equals(CMS_SPREAD), false);
    modifiedCMSSpread =
        new CapFloorCMSSpread(
            CUR,
            PAYMENT_TIME,
            PAYMENT_ACCRUAL_FACTOR,
            NOTIONAL,
            FIXING_TIME,
            SWAP_1,
            CMS_INDEX_1,
            SWAP_2,
            CMS_INDEX_2,
            SETTLEMENT_TIME,
            STRIKE + 1.0,
            IS_CAP,
            FUNDING_CURVE_NAME);
    assertEquals(modifiedCMSSpread.equals(CMS_SPREAD), false);
    modifiedCMSSpread =
        new CapFloorCMSSpread(
            CUR,
            PAYMENT_TIME,
            PAYMENT_ACCRUAL_FACTOR,
            NOTIONAL,
            FIXING_TIME,
            SWAP_1,
            CMS_INDEX_1,
            SWAP_2,
            CMS_INDEX_2,
            SETTLEMENT_TIME,
            STRIKE,
            !IS_CAP,
            FUNDING_CURVE_NAME);
    assertEquals(modifiedCMSSpread.equals(CMS_SPREAD), false);
    modifiedCMSSpread =
        new CapFloorCMSSpread(
            CUR,
            PAYMENT_TIME,
            PAYMENT_ACCRUAL_FACTOR,
            NOTIONAL,
            FIXING_TIME,
            SWAP_2,
            CMS_INDEX_1,
            SWAP_2,
            CMS_INDEX_2,
            SETTLEMENT_TIME,
            STRIKE,
            IS_CAP,
            FUNDING_CURVE_NAME);
    assertEquals(modifiedCMSSpread.equals(CMS_SPREAD), false);
    modifiedCMSSpread =
        new CapFloorCMSSpread(
            CUR,
            PAYMENT_TIME,
            PAYMENT_ACCRUAL_FACTOR,
            NOTIONAL,
            FIXING_TIME,
            SWAP_1,
            CMS_INDEX_2,
            SWAP_2,
            CMS_INDEX_2,
            SETTLEMENT_TIME,
            STRIKE,
            IS_CAP,
            FUNDING_CURVE_NAME);
    assertEquals(modifiedCMSSpread.equals(CMS_SPREAD), false);
    modifiedCMSSpread =
        new CapFloorCMSSpread(
            CUR,
            PAYMENT_TIME,
            PAYMENT_ACCRUAL_FACTOR,
            NOTIONAL,
            FIXING_TIME,
            SWAP_1,
            CMS_INDEX_1,
            SWAP_1,
            CMS_INDEX_2,
            SETTLEMENT_TIME,
            STRIKE,
            IS_CAP,
            FUNDING_CURVE_NAME);
    assertEquals(modifiedCMSSpread.equals(CMS_SPREAD), false);
    modifiedCMSSpread =
        new CapFloorCMSSpread(
            CUR,
            PAYMENT_TIME,
            PAYMENT_ACCRUAL_FACTOR,
            NOTIONAL,
            FIXING_TIME,
            SWAP_1,
            CMS_INDEX_1,
            SWAP_2,
            CMS_INDEX_1,
            SETTLEMENT_TIME,
            STRIKE,
            IS_CAP,
            FUNDING_CURVE_NAME);
    assertEquals(modifiedCMSSpread.equals(CMS_SPREAD), false);
  }
}
/**
 * Class to test the present value and present value rate sensitivity of the cash-settled European
 * swaption in the SABR with extrapolation method. The SABR smile is extrapolated above a certain
 * cut-off strike.
 */
public class SwaptionCashFixedIborSABRExtrapolationRightMethodTest {
  // Swaption description
  private static final ZonedDateTime EXPIRY_DATE = DateUtils.getUTCDate(2014, 3, 18);
  private static final boolean IS_LONG = true;
  private static final int SETTLEMENT_DAYS = 2;
  // Swap 5Y description
  private static final Currency CUR = Currency.USD;
  private static final Calendar CALENDAR = new MondayToFridayCalendar("A");
  private static final BusinessDayConvention BUSINESS_DAY =
      BusinessDayConventionFactory.INSTANCE.getBusinessDayConvention("Modified Following");
  private static final boolean IS_EOM = true;
  private static final int ANNUITY_TENOR_YEAR = 5;
  private static final Period ANNUITY_TENOR = Period.ofYears(ANNUITY_TENOR_YEAR);
  private static final ZonedDateTime SETTLEMENT_DATE =
      ScheduleCalculator.getAdjustedDate(EXPIRY_DATE, SETTLEMENT_DAYS, CALENDAR);
  private static final double NOTIONAL = 100000000; // 100m
  //  Fixed leg: Semi-annual bond
  private static final Period FIXED_PAYMENT_PERIOD = Period.ofMonths(6);
  private static final DayCount FIXED_DAY_COUNT = DayCountFactory.INSTANCE.getDayCount("30/360");
  private static final double RATE = 0.04;
  private static final boolean FIXED_IS_PAYER = true;
  //  Ibor leg: quarterly money
  private static final Period INDEX_TENOR = Period.ofMonths(3);
  private static final DayCount DAY_COUNT = DayCountFactory.INSTANCE.getDayCount("Actual/360");
  private static final IborIndex IBOR_INDEX =
      new IborIndex(CUR, INDEX_TENOR, SETTLEMENT_DAYS, CALENDAR, DAY_COUNT, BUSINESS_DAY, IS_EOM);
  // Swaption construction
  private static final IndexSwap CMS_INDEX =
      new IndexSwap(FIXED_PAYMENT_PERIOD, FIXED_DAY_COUNT, IBOR_INDEX, ANNUITY_TENOR);
  private static final SwapFixedIborDefinition SWAP_DEFINITION_PAYER =
      SwapFixedIborDefinition.from(SETTLEMENT_DATE, CMS_INDEX, NOTIONAL, RATE, FIXED_IS_PAYER);
  private static final SwapFixedIborDefinition SWAP_DEFINITION_RECEIVER =
      SwapFixedIborDefinition.from(SETTLEMENT_DATE, CMS_INDEX, NOTIONAL, RATE, !FIXED_IS_PAYER);
  private static final SwaptionCashFixedIborDefinition SWAPTION_DEFINITION_LONG_PAYER =
      SwaptionCashFixedIborDefinition.from(EXPIRY_DATE, SWAP_DEFINITION_PAYER, IS_LONG);
  private static final SwaptionCashFixedIborDefinition SWAPTION_DEFINITION_LONG_RECEIVER =
      SwaptionCashFixedIborDefinition.from(EXPIRY_DATE, SWAP_DEFINITION_RECEIVER, IS_LONG);
  private static final SwaptionCashFixedIborDefinition SWAPTION_DEFINITION_SHORT_PAYER =
      SwaptionCashFixedIborDefinition.from(EXPIRY_DATE, SWAP_DEFINITION_PAYER, !IS_LONG);
  private static final SwaptionCashFixedIborDefinition SWAPTION_DEFINITION_SHORT_RECEIVER =
      SwaptionCashFixedIborDefinition.from(EXPIRY_DATE, SWAP_DEFINITION_RECEIVER, !IS_LONG);
  // to derivatives
  private static final ZonedDateTime REFERENCE_DATE = DateUtils.getUTCDate(2008, 8, 18);
  private static final String FUNDING_CURVE_NAME = "Funding";
  private static final String FORWARD_CURVE_NAME = "Forward";
  private static final String[] CURVES_NAME = {FUNDING_CURVE_NAME, FORWARD_CURVE_NAME};
  private static final SwaptionCashFixedIbor SWAPTION_LONG_PAYER =
      SWAPTION_DEFINITION_LONG_PAYER.toDerivative(REFERENCE_DATE, CURVES_NAME);
  private static final SwaptionCashFixedIbor SWAPTION_LONG_RECEIVER =
      SWAPTION_DEFINITION_LONG_RECEIVER.toDerivative(REFERENCE_DATE, CURVES_NAME);
  private static final SwaptionCashFixedIbor SWAPTION_SHORT_PAYER =
      SWAPTION_DEFINITION_SHORT_PAYER.toDerivative(REFERENCE_DATE, CURVES_NAME);
  private static final SwaptionCashFixedIbor SWAPTION_SHORT_RECEIVER =
      SWAPTION_DEFINITION_SHORT_RECEIVER.toDerivative(REFERENCE_DATE, CURVES_NAME);
  // Extrapolation
  private static final double CUT_OFF_STRIKE = 0.08;
  private static final double MU = 10.0;
  private static final SwaptionCashFixedIborSABRExtrapolationRightMethod METHOD_EXTRAPOLATION =
      new SwaptionCashFixedIborSABRExtrapolationRightMethod(CUT_OFF_STRIKE, MU);
  // Calculators
  private static final PresentValueSABRExtrapolationCalculator PVC =
      PresentValueSABRExtrapolationCalculator.getInstance();

  /** Tests present value in the region where there is no extrapolation. Tests long/short parity. */
  @Test
  public void testPresentValueNoExtra() {
    final YieldCurveBundle curves = TestsDataSetsSABR.createCurves1();
    final SABRInterestRateParameters sabrParameter =
        TestsDataSetsSABR.createSABRExtrapolation1(CUT_OFF_STRIKE, MU);
    final SABRInterestRateDataBundle sabrBundle =
        new SABRInterestRateDataBundle(sabrParameter, curves);
    final SwaptionCashFixedIborSABRExtrapolationRightMethod method =
        new SwaptionCashFixedIborSABRExtrapolationRightMethod(CUT_OFF_STRIKE, MU);
    final double priceLongPayer = method.presentValue(SWAPTION_LONG_PAYER, sabrBundle);
    final double priceShortPayer = method.presentValue(SWAPTION_SHORT_PAYER, sabrBundle);
    final double priceLongReceiver = method.presentValue(SWAPTION_LONG_RECEIVER, sabrBundle);
    final double priceShortReceiver = method.presentValue(SWAPTION_SHORT_RECEIVER, sabrBundle);
    final double priceLongPayerNoExtra = PVC.visit(SWAPTION_LONG_PAYER, sabrBundle);
    final double priceShortPayerNoExtra = PVC.visit(SWAPTION_SHORT_PAYER, sabrBundle);
    final double priceLongReceiverNoExtra = PVC.visit(SWAPTION_LONG_RECEIVER, sabrBundle);
    final double priceShortReceiverNoExtra = PVC.visit(SWAPTION_SHORT_RECEIVER, sabrBundle);
    assertEquals(
        "Swaption cash SABR extrapolation: below cut-off strike",
        priceLongPayerNoExtra,
        priceLongPayer,
        1E-2);
    assertEquals(
        "Swaption cash SABR extrapolation: below cut-off strike",
        priceShortPayerNoExtra,
        priceShortPayer,
        1E-2);
    assertEquals(
        "Swaption cash SABR extrapolation: below cut-off strike",
        priceLongReceiverNoExtra,
        priceLongReceiver,
        1E-2);
    assertEquals(
        "Swaption cash SABR extrapolation: below cut-off strike",
        priceShortReceiverNoExtra,
        priceShortReceiver,
        1E-2);
    assertEquals(
        "Swaption cash SABR extrapolation: below cut-off strike long/short parity",
        priceLongPayer,
        -priceShortPayer,
        1E-2);
    assertEquals(
        "Swaption cash SABR extrapolation: below cut-off strike long/short parity",
        priceLongReceiver,
        -priceShortReceiver,
        1E-2);
  }

  /**
   * Tests present value in the region where there is extrapolation. Test a hard-coded value. Tests
   * long/short parity. Test payer/receiver/swap parity.
   */
  @Test
  public void testPresentValueExtra() {
    final YieldCurveBundle curves = TestsDataSetsSABR.createCurves1();
    final SABRInterestRateParameters sabrParameter = TestsDataSetsSABR.createSABR1();
    final SABRInterestRateDataBundle sabrBundle =
        new SABRInterestRateDataBundle(sabrParameter, curves);
    final double highStrike = 0.10;
    final SwapFixedIborDefinition swapDefinitionPayerHighStrike =
        SwapFixedIborDefinition.from(
            SETTLEMENT_DATE, CMS_INDEX, NOTIONAL, highStrike, FIXED_IS_PAYER);
    final SwapFixedIborDefinition swapDefinitionReceiverHighStrike =
        SwapFixedIborDefinition.from(
            SETTLEMENT_DATE, CMS_INDEX, NOTIONAL, highStrike, !FIXED_IS_PAYER);
    final SwaptionCashFixedIborDefinition swaptionDefinitionLongPayerHighStrike =
        SwaptionCashFixedIborDefinition.from(EXPIRY_DATE, swapDefinitionPayerHighStrike, IS_LONG);
    final SwaptionCashFixedIborDefinition swaptionDefinitionShortPayerHighStrike =
        SwaptionCashFixedIborDefinition.from(EXPIRY_DATE, swapDefinitionPayerHighStrike, !IS_LONG);
    final SwaptionCashFixedIborDefinition swaptionDefinitionLongReceiverHighStrike =
        SwaptionCashFixedIborDefinition.from(
            EXPIRY_DATE, swapDefinitionReceiverHighStrike, IS_LONG);
    final SwaptionCashFixedIbor swaptionLongPayerHighStrike =
        swaptionDefinitionLongPayerHighStrike.toDerivative(REFERENCE_DATE, CURVES_NAME);
    final SwaptionCashFixedIbor swaptionShortPayerHighStrike =
        swaptionDefinitionShortPayerHighStrike.toDerivative(REFERENCE_DATE, CURVES_NAME);
    final SwaptionCashFixedIbor swaptionLongReceiverHighStrike =
        swaptionDefinitionLongReceiverHighStrike.toDerivative(REFERENCE_DATE, CURVES_NAME);
    final SwaptionCashFixedIborSABRExtrapolationRightMethod method =
        new SwaptionCashFixedIborSABRExtrapolationRightMethod(CUT_OFF_STRIKE, MU);
    final double priceLongPayer = method.presentValue(swaptionLongPayerHighStrike, sabrBundle);
    final double priceShortPayer = method.presentValue(swaptionShortPayerHighStrike, sabrBundle);
    final double priceLongReceiver =
        method.presentValue(swaptionLongReceiverHighStrike, sabrBundle);
    final double priceLongPayerExpected = 557829.033; // Value from previous run
    final double priceLongReceiverExpected = 20759354.082; // Value from previous run
    assertEquals(
        "Swaption cash SABR extrapolation: fixed value",
        priceLongPayerExpected,
        priceLongPayer,
        1E-2);
    assertEquals(
        "Swaption cash SABR extrapolation: fixed value",
        priceLongReceiverExpected,
        priceLongReceiver,
        1E-2);
    assertEquals(
        "Swaption cash SABR extrapolation: long/short parity",
        priceLongPayer,
        -priceShortPayer,
        1E-2);
  }

  @Test
  /**
   * Test the present value sensitivity to rate for a swaption with strike above the cut-off strike.
   */
  public void testPresentValueSensitivityExtra() {
    final YieldCurveBundle curves = TestsDataSetsSABR.createCurves1();
    final SABRInterestRateParameters sabrParameter = TestsDataSetsSABR.createSABR1();
    final SABRInterestRateDataBundle sabrBundle =
        new SABRInterestRateDataBundle(sabrParameter, curves);
    final double highStrike = 0.10;
    final SwapFixedIborDefinition swapDefinitionPayerHighStrike =
        SwapFixedIborDefinition.from(
            SETTLEMENT_DATE, CMS_INDEX, NOTIONAL, highStrike, FIXED_IS_PAYER);
    final SwaptionCashFixedIborDefinition swaptionDefinitionLongPayerHighStrike =
        SwaptionCashFixedIborDefinition.from(EXPIRY_DATE, swapDefinitionPayerHighStrike, IS_LONG);
    final SwaptionCashFixedIborDefinition swaptionDefinitionShortPayerHighStrike =
        SwaptionCashFixedIborDefinition.from(EXPIRY_DATE, swapDefinitionPayerHighStrike, !IS_LONG);
    final SwaptionCashFixedIbor swaptionLongPayerHighStrike =
        swaptionDefinitionLongPayerHighStrike.toDerivative(REFERENCE_DATE, CURVES_NAME);
    final SwaptionCashFixedIbor swaptionShortPayerHighStrike =
        swaptionDefinitionShortPayerHighStrike.toDerivative(REFERENCE_DATE, CURVES_NAME);
    final SwaptionCashFixedIborSABRExtrapolationRightMethod methodExtra =
        new SwaptionCashFixedIborSABRExtrapolationRightMethod(CUT_OFF_STRIKE, MU);
    // Swaption sensitivity
    InterestRateCurveSensitivity pvsLongPayerExtra =
        methodExtra.presentValueSensitivity(swaptionLongPayerHighStrike, sabrBundle);
    final InterestRateCurveSensitivity pvsShortPayerExtra =
        methodExtra.presentValueSensitivity(swaptionShortPayerHighStrike, sabrBundle);
    // Long/short parity
    final InterestRateCurveSensitivity pvsShortPayer_1 = pvsShortPayerExtra.multiply(-1);
    assertEquals(pvsLongPayerExtra.getSensitivities(), pvsShortPayer_1.getSensitivities());
    // Present value sensitivity comparison with finite difference.
    final double deltaTolerance = 5.0E+4;
    // Testing note: Sensitivity is for a movement of 1. 1E+2 = 1 cent for a 1 bp move. Tolerance
    // increased to cope with numerical imprecision of finite difference.
    final double deltaShift = 1.0E-5;
    pvsLongPayerExtra = pvsLongPayerExtra.clean();
    final double pv = methodExtra.presentValue(swaptionLongPayerHighStrike, sabrBundle);
    // 1. Forward curve sensitivity
    final String bumpedCurveName = "Bumped Curve";
    final String[] bumpedCurvesForwardName = {FUNDING_CURVE_NAME, bumpedCurveName};
    final SwaptionCashFixedIbor swaptionBumpedForward =
        swaptionDefinitionLongPayerHighStrike.toDerivative(REFERENCE_DATE, bumpedCurvesForwardName);
    final YieldAndDiscountCurve curveForward = curves.getCurve(FORWARD_CURVE_NAME);
    final Set<Double> timeForwardSet = new TreeSet<Double>();
    for (final Payment pay :
        swaptionLongPayerHighStrike.getUnderlyingSwap().getSecondLeg().getPayments()) {
      final CouponIbor coupon = (CouponIbor) pay;
      timeForwardSet.add(coupon.getFixingPeriodStartTime());
      timeForwardSet.add(coupon.getFixingPeriodEndTime());
    }
    final int nbForwardDate = timeForwardSet.size();
    final List<Double> timeForwardList = new ArrayList<Double>(timeForwardSet);
    Double[] timeForwardArray = new Double[nbForwardDate];
    timeForwardArray = timeForwardList.toArray(timeForwardArray);
    final double[] yieldsForward = new double[nbForwardDate + 1];
    final double[] nodeTimesForward = new double[nbForwardDate + 1];
    yieldsForward[0] = curveForward.getInterestRate(0.0);
    for (int i = 0; i < nbForwardDate; i++) {
      nodeTimesForward[i + 1] = timeForwardArray[i];
      yieldsForward[i + 1] = curveForward.getInterestRate(nodeTimesForward[i + 1]);
    }
    final YieldAndDiscountCurve tempCurveForward =
        new YieldCurve(
            InterpolatedDoublesCurve.fromSorted(
                nodeTimesForward, yieldsForward, new LinearInterpolator1D()));
    final List<DoublesPair> tempForward =
        pvsLongPayerExtra.getSensitivities().get(FORWARD_CURVE_NAME);
    final double[] resFwd = new double[nbForwardDate];
    for (int i = 0; i < nbForwardDate; i++) {
      final YieldAndDiscountCurve bumpedCurveForward =
          tempCurveForward.withSingleShift(nodeTimesForward[i + 1], deltaShift);
      final YieldCurveBundle curvesBumpedForward = new YieldCurveBundle();
      curvesBumpedForward.addAll(curves);
      curvesBumpedForward.setCurve("Bumped Curve", bumpedCurveForward);
      final SABRInterestRateDataBundle sabrBundleBumped =
          new SABRInterestRateDataBundle(sabrParameter, curvesBumpedForward);
      final double bumpedpv = methodExtra.presentValue(swaptionBumpedForward, sabrBundleBumped);
      resFwd[i] = (bumpedpv - pv) / deltaShift;
      final DoublesPair pair = tempForward.get(i);
      assertEquals(
          "Sensitivity to forward curve: Node " + i,
          nodeTimesForward[i + 1],
          pair.getFirst(),
          1E-8);
      assertEquals(
          "Sensitivity to forward curve: Node " + i, resFwd[i], pair.getSecond(), deltaTolerance);
    }
    // 2. Funding curve sensitivity
    final String[] bumpedCurvesFundingName = {bumpedCurveName, FORWARD_CURVE_NAME};
    final SwaptionCashFixedIbor swaptionBumpedFunding =
        swaptionDefinitionLongPayerHighStrike.toDerivative(REFERENCE_DATE, bumpedCurvesFundingName);
    final int nbPayDate =
        swaptionDefinitionLongPayerHighStrike.getUnderlyingSwap().getIborLeg().getPayments().length;
    final YieldAndDiscountCurve curveFunding = curves.getCurve(FUNDING_CURVE_NAME);
    final double[] yieldsFunding = new double[nbPayDate + 2];
    final double[] nodeTimesFunding = new double[nbPayDate + 2];
    yieldsFunding[0] = curveFunding.getInterestRate(0.0);
    nodeTimesFunding[1] = swaptionLongPayerHighStrike.getSettlementTime();
    yieldsFunding[1] = curveFunding.getInterestRate(nodeTimesFunding[1]);
    for (int i = 0; i < nbPayDate; i++) {
      nodeTimesFunding[i + 2] =
          swaptionLongPayerHighStrike
              .getUnderlyingSwap()
              .getSecondLeg()
              .getNthPayment(i)
              .getPaymentTime();
      yieldsFunding[i + 2] = curveFunding.getInterestRate(nodeTimesFunding[i + 2]);
    }
    final YieldAndDiscountCurve tempCurveFunding =
        new YieldCurve(
            InterpolatedDoublesCurve.fromSorted(
                nodeTimesFunding, yieldsFunding, new LinearInterpolator1D()));
    final List<DoublesPair> tempFunding =
        pvsLongPayerExtra.getSensitivities().get(FUNDING_CURVE_NAME);
    final double[] resDsc = new double[nbPayDate];
    for (int i = 0; i < nbPayDate; i++) {
      final YieldAndDiscountCurve bumpedCurve =
          tempCurveFunding.withSingleShift(nodeTimesFunding[i + 1], deltaShift);
      final YieldCurveBundle curvesBumped = new YieldCurveBundle();
      curvesBumped.addAll(curves);
      curvesBumped.setCurve("Bumped Curve", bumpedCurve);
      final SABRInterestRateDataBundle sabrBundleBumped =
          new SABRInterestRateDataBundle(sabrParameter, curvesBumped);
      final double bumpedpv = methodExtra.presentValue(swaptionBumpedFunding, sabrBundleBumped);
      resDsc[i] = (bumpedpv - pv) / deltaShift;
      final DoublesPair pair = tempFunding.get(i);
      assertEquals(
          "Sensitivity to discounting curve: Node " + i,
          nodeTimesFunding[i + 1],
          pair.getFirst(),
          1E-8);
      assertEquals(
          "Sensitivity to discounting curve: Node " + i,
          resDsc[i],
          pair.getSecond(),
          deltaTolerance);
    }
  }

  @Test
  /**
   * Test the present value sensitivity to SABR parameters for a swaption with strike above the
   * cut-off strike.
   */
  public void testPresentValueSABRSensitivity() {
    final YieldCurveBundle curves = TestsDataSetsSABR.createCurves1();
    final SABRInterestRateParameters sabrParameter = TestsDataSetsSABR.createSABR1();
    final SABRInterestRateDataBundle sabrBundle =
        new SABRInterestRateDataBundle(sabrParameter, curves);
    final double highStrike = 0.10;
    final SwapFixedIborDefinition swapDefinitionPayerHighStrike =
        SwapFixedIborDefinition.from(
            SETTLEMENT_DATE, CMS_INDEX, NOTIONAL, highStrike, FIXED_IS_PAYER);
    final SwaptionCashFixedIborDefinition swaptionDefinitionLongPayerHighStrike =
        SwaptionCashFixedIborDefinition.from(EXPIRY_DATE, swapDefinitionPayerHighStrike, IS_LONG);
    final SwaptionCashFixedIborDefinition swaptionDefinitionShortPayerHighStrike =
        SwaptionCashFixedIborDefinition.from(EXPIRY_DATE, swapDefinitionPayerHighStrike, !IS_LONG);
    final SwaptionCashFixedIbor swaptionLongPayerHighStrike =
        swaptionDefinitionLongPayerHighStrike.toDerivative(REFERENCE_DATE, CURVES_NAME);
    final SwaptionCashFixedIbor swaptionShortPayerHighStrike =
        swaptionDefinitionShortPayerHighStrike.toDerivative(REFERENCE_DATE, CURVES_NAME);
    //    SwaptionCashFixedIborSABRExtrapolationRightMethod methodExtra = new
    // SwaptionCashFixedIborSABRExtrapolationRightMethod(CUT_OFF_STRIKE, MU);
    // Swaption sensitivity
    final PresentValueSABRSensitivityDataBundle pvsLongPayer =
        METHOD_EXTRAPOLATION.presentValueSABRSensitivity(swaptionLongPayerHighStrike, sabrBundle);
    PresentValueSABRSensitivityDataBundle pvsShortPayer =
        METHOD_EXTRAPOLATION.presentValueSABRSensitivity(swaptionShortPayerHighStrike, sabrBundle);
    // Long/short parity
    pvsShortPayer = PresentValueSABRSensitivityDataBundle.multiplyBy(pvsShortPayer, -1.0);
    assertEquals(pvsLongPayer.getAlpha(), pvsShortPayer.getAlpha());
    // SABR sensitivity vs finite difference
    final double pvLongPayer =
        METHOD_EXTRAPOLATION.presentValue(swaptionLongPayerHighStrike, sabrBundle);
    final DoublesPair expectedExpiryTenor =
        new DoublesPair(swaptionLongPayerHighStrike.getTimeToExpiry(), ANNUITY_TENOR_YEAR);
    final double shift = 0.000005;
    // Alpha sensitivity vs finite difference computation
    final SABRInterestRateParameters sabrParameterAlphaBumped =
        TestsDataSetsSABR.createSABR1AlphaBumped(shift);
    final SABRInterestRateDataBundle sabrBundleAlphaBumped =
        new SABRInterestRateDataBundle(sabrParameterAlphaBumped, curves);
    final double pvLongPayerAlphaBumped =
        METHOD_EXTRAPOLATION.presentValue(swaptionLongPayerHighStrike, sabrBundleAlphaBumped);
    final double expectedAlphaSensi = (pvLongPayerAlphaBumped - pvLongPayer) / shift;
    assertEquals(
        "Number of alpha sensitivity", pvsLongPayer.getAlpha().getMap().keySet().size(), 1);
    assertEquals(
        "Alpha sensitivity expiry/tenor",
        pvsLongPayer.getAlpha().getMap().keySet().contains(expectedExpiryTenor),
        true);
    assertEquals(
        "Alpha sensitivity value",
        expectedAlphaSensi,
        pvsLongPayer.getAlpha().getMap().get(expectedExpiryTenor),
        2.0E+3);
    // Rho sensitivity vs finite difference computation
    final SABRInterestRateParameters sabrParameterRhoBumped =
        TestsDataSetsSABR.createSABR1RhoBumped(shift);
    final SABRInterestRateDataBundle sabrBundleRhoBumped =
        new SABRInterestRateDataBundle(sabrParameterRhoBumped, curves);
    final double pvLongPayerRhoBumped =
        METHOD_EXTRAPOLATION.presentValue(swaptionLongPayerHighStrike, sabrBundleRhoBumped);
    final double expectedRhoSensi = (pvLongPayerRhoBumped - pvLongPayer) / shift;
    assertEquals("Number of rho sensitivity", pvsLongPayer.getRho().getMap().keySet().size(), 1);
    assertEquals(
        "Rho sensitivity expiry/tenor",
        pvsLongPayer.getRho().getMap().keySet().contains(expectedExpiryTenor),
        true);
    assertEquals(
        "Rho sensitivity value",
        expectedRhoSensi,
        pvsLongPayer.getRho().getMap().get(expectedExpiryTenor),
        1.0E+0);
    // Alpha sensitivity vs finite difference computation
    final SABRInterestRateParameters sabrParameterNuBumped =
        TestsDataSetsSABR.createSABR1NuBumped(shift);
    final SABRInterestRateDataBundle sabrBundleNuBumped =
        new SABRInterestRateDataBundle(sabrParameterNuBumped, curves);
    final double pvLongPayerNuBumped =
        METHOD_EXTRAPOLATION.presentValue(swaptionLongPayerHighStrike, sabrBundleNuBumped);
    final double expectedNuSensi = (pvLongPayerNuBumped - pvLongPayer) / shift;
    assertEquals("Number of nu sensitivity", pvsLongPayer.getNu().getMap().keySet().size(), 1);
    assertEquals(
        "Nu sensitivity expiry/tenor",
        pvsLongPayer.getNu().getMap().keySet().contains(expectedExpiryTenor),
        true);
    assertEquals(
        "Nu sensitivity value",
        expectedNuSensi,
        pvsLongPayer.getNu().getMap().get(expectedExpiryTenor),
        5.0E+1);
  }
}
 @Test
 /**
  * Test the present value sensitivity to SABR parameters for a swaption with strike above the
  * cut-off strike.
  */
 public void testPresentValueSABRSensitivity() {
   final YieldCurveBundle curves = TestsDataSetsSABR.createCurves1();
   final SABRInterestRateParameters sabrParameter = TestsDataSetsSABR.createSABR1();
   final SABRInterestRateDataBundle sabrBundle =
       new SABRInterestRateDataBundle(sabrParameter, curves);
   final double highStrike = 0.10;
   final SwapFixedIborDefinition swapDefinitionPayerHighStrike =
       SwapFixedIborDefinition.from(
           SETTLEMENT_DATE, CMS_INDEX, NOTIONAL, highStrike, FIXED_IS_PAYER);
   final SwaptionCashFixedIborDefinition swaptionDefinitionLongPayerHighStrike =
       SwaptionCashFixedIborDefinition.from(EXPIRY_DATE, swapDefinitionPayerHighStrike, IS_LONG);
   final SwaptionCashFixedIborDefinition swaptionDefinitionShortPayerHighStrike =
       SwaptionCashFixedIborDefinition.from(EXPIRY_DATE, swapDefinitionPayerHighStrike, !IS_LONG);
   final SwaptionCashFixedIbor swaptionLongPayerHighStrike =
       swaptionDefinitionLongPayerHighStrike.toDerivative(REFERENCE_DATE, CURVES_NAME);
   final SwaptionCashFixedIbor swaptionShortPayerHighStrike =
       swaptionDefinitionShortPayerHighStrike.toDerivative(REFERENCE_DATE, CURVES_NAME);
   //    SwaptionCashFixedIborSABRExtrapolationRightMethod methodExtra = new
   // SwaptionCashFixedIborSABRExtrapolationRightMethod(CUT_OFF_STRIKE, MU);
   // Swaption sensitivity
   final PresentValueSABRSensitivityDataBundle pvsLongPayer =
       METHOD_EXTRAPOLATION.presentValueSABRSensitivity(swaptionLongPayerHighStrike, sabrBundle);
   PresentValueSABRSensitivityDataBundle pvsShortPayer =
       METHOD_EXTRAPOLATION.presentValueSABRSensitivity(swaptionShortPayerHighStrike, sabrBundle);
   // Long/short parity
   pvsShortPayer = PresentValueSABRSensitivityDataBundle.multiplyBy(pvsShortPayer, -1.0);
   assertEquals(pvsLongPayer.getAlpha(), pvsShortPayer.getAlpha());
   // SABR sensitivity vs finite difference
   final double pvLongPayer =
       METHOD_EXTRAPOLATION.presentValue(swaptionLongPayerHighStrike, sabrBundle);
   final DoublesPair expectedExpiryTenor =
       new DoublesPair(swaptionLongPayerHighStrike.getTimeToExpiry(), ANNUITY_TENOR_YEAR);
   final double shift = 0.000005;
   // Alpha sensitivity vs finite difference computation
   final SABRInterestRateParameters sabrParameterAlphaBumped =
       TestsDataSetsSABR.createSABR1AlphaBumped(shift);
   final SABRInterestRateDataBundle sabrBundleAlphaBumped =
       new SABRInterestRateDataBundle(sabrParameterAlphaBumped, curves);
   final double pvLongPayerAlphaBumped =
       METHOD_EXTRAPOLATION.presentValue(swaptionLongPayerHighStrike, sabrBundleAlphaBumped);
   final double expectedAlphaSensi = (pvLongPayerAlphaBumped - pvLongPayer) / shift;
   assertEquals(
       "Number of alpha sensitivity", pvsLongPayer.getAlpha().getMap().keySet().size(), 1);
   assertEquals(
       "Alpha sensitivity expiry/tenor",
       pvsLongPayer.getAlpha().getMap().keySet().contains(expectedExpiryTenor),
       true);
   assertEquals(
       "Alpha sensitivity value",
       expectedAlphaSensi,
       pvsLongPayer.getAlpha().getMap().get(expectedExpiryTenor),
       2.0E+3);
   // Rho sensitivity vs finite difference computation
   final SABRInterestRateParameters sabrParameterRhoBumped =
       TestsDataSetsSABR.createSABR1RhoBumped(shift);
   final SABRInterestRateDataBundle sabrBundleRhoBumped =
       new SABRInterestRateDataBundle(sabrParameterRhoBumped, curves);
   final double pvLongPayerRhoBumped =
       METHOD_EXTRAPOLATION.presentValue(swaptionLongPayerHighStrike, sabrBundleRhoBumped);
   final double expectedRhoSensi = (pvLongPayerRhoBumped - pvLongPayer) / shift;
   assertEquals("Number of rho sensitivity", pvsLongPayer.getRho().getMap().keySet().size(), 1);
   assertEquals(
       "Rho sensitivity expiry/tenor",
       pvsLongPayer.getRho().getMap().keySet().contains(expectedExpiryTenor),
       true);
   assertEquals(
       "Rho sensitivity value",
       expectedRhoSensi,
       pvsLongPayer.getRho().getMap().get(expectedExpiryTenor),
       1.0E+0);
   // Alpha sensitivity vs finite difference computation
   final SABRInterestRateParameters sabrParameterNuBumped =
       TestsDataSetsSABR.createSABR1NuBumped(shift);
   final SABRInterestRateDataBundle sabrBundleNuBumped =
       new SABRInterestRateDataBundle(sabrParameterNuBumped, curves);
   final double pvLongPayerNuBumped =
       METHOD_EXTRAPOLATION.presentValue(swaptionLongPayerHighStrike, sabrBundleNuBumped);
   final double expectedNuSensi = (pvLongPayerNuBumped - pvLongPayer) / shift;
   assertEquals("Number of nu sensitivity", pvsLongPayer.getNu().getMap().keySet().size(), 1);
   assertEquals(
       "Nu sensitivity expiry/tenor",
       pvsLongPayer.getNu().getMap().keySet().contains(expectedExpiryTenor),
       true);
   assertEquals(
       "Nu sensitivity value",
       expectedNuSensi,
       pvsLongPayer.getNu().getMap().get(expectedExpiryTenor),
       5.0E+1);
 }
 @Test
 /**
  * Test the present value sensitivity to rate for a swaption with strike above the cut-off strike.
  */
 public void testPresentValueSensitivityExtra() {
   final YieldCurveBundle curves = TestsDataSetsSABR.createCurves1();
   final SABRInterestRateParameters sabrParameter = TestsDataSetsSABR.createSABR1();
   final SABRInterestRateDataBundle sabrBundle =
       new SABRInterestRateDataBundle(sabrParameter, curves);
   final double highStrike = 0.10;
   final SwapFixedIborDefinition swapDefinitionPayerHighStrike =
       SwapFixedIborDefinition.from(
           SETTLEMENT_DATE, CMS_INDEX, NOTIONAL, highStrike, FIXED_IS_PAYER);
   final SwaptionCashFixedIborDefinition swaptionDefinitionLongPayerHighStrike =
       SwaptionCashFixedIborDefinition.from(EXPIRY_DATE, swapDefinitionPayerHighStrike, IS_LONG);
   final SwaptionCashFixedIborDefinition swaptionDefinitionShortPayerHighStrike =
       SwaptionCashFixedIborDefinition.from(EXPIRY_DATE, swapDefinitionPayerHighStrike, !IS_LONG);
   final SwaptionCashFixedIbor swaptionLongPayerHighStrike =
       swaptionDefinitionLongPayerHighStrike.toDerivative(REFERENCE_DATE, CURVES_NAME);
   final SwaptionCashFixedIbor swaptionShortPayerHighStrike =
       swaptionDefinitionShortPayerHighStrike.toDerivative(REFERENCE_DATE, CURVES_NAME);
   final SwaptionCashFixedIborSABRExtrapolationRightMethod methodExtra =
       new SwaptionCashFixedIborSABRExtrapolationRightMethod(CUT_OFF_STRIKE, MU);
   // Swaption sensitivity
   InterestRateCurveSensitivity pvsLongPayerExtra =
       methodExtra.presentValueSensitivity(swaptionLongPayerHighStrike, sabrBundle);
   final InterestRateCurveSensitivity pvsShortPayerExtra =
       methodExtra.presentValueSensitivity(swaptionShortPayerHighStrike, sabrBundle);
   // Long/short parity
   final InterestRateCurveSensitivity pvsShortPayer_1 = pvsShortPayerExtra.multiply(-1);
   assertEquals(pvsLongPayerExtra.getSensitivities(), pvsShortPayer_1.getSensitivities());
   // Present value sensitivity comparison with finite difference.
   final double deltaTolerance = 5.0E+4;
   // Testing note: Sensitivity is for a movement of 1. 1E+2 = 1 cent for a 1 bp move. Tolerance
   // increased to cope with numerical imprecision of finite difference.
   final double deltaShift = 1.0E-5;
   pvsLongPayerExtra = pvsLongPayerExtra.clean();
   final double pv = methodExtra.presentValue(swaptionLongPayerHighStrike, sabrBundle);
   // 1. Forward curve sensitivity
   final String bumpedCurveName = "Bumped Curve";
   final String[] bumpedCurvesForwardName = {FUNDING_CURVE_NAME, bumpedCurveName};
   final SwaptionCashFixedIbor swaptionBumpedForward =
       swaptionDefinitionLongPayerHighStrike.toDerivative(REFERENCE_DATE, bumpedCurvesForwardName);
   final YieldAndDiscountCurve curveForward = curves.getCurve(FORWARD_CURVE_NAME);
   final Set<Double> timeForwardSet = new TreeSet<Double>();
   for (final Payment pay :
       swaptionLongPayerHighStrike.getUnderlyingSwap().getSecondLeg().getPayments()) {
     final CouponIbor coupon = (CouponIbor) pay;
     timeForwardSet.add(coupon.getFixingPeriodStartTime());
     timeForwardSet.add(coupon.getFixingPeriodEndTime());
   }
   final int nbForwardDate = timeForwardSet.size();
   final List<Double> timeForwardList = new ArrayList<Double>(timeForwardSet);
   Double[] timeForwardArray = new Double[nbForwardDate];
   timeForwardArray = timeForwardList.toArray(timeForwardArray);
   final double[] yieldsForward = new double[nbForwardDate + 1];
   final double[] nodeTimesForward = new double[nbForwardDate + 1];
   yieldsForward[0] = curveForward.getInterestRate(0.0);
   for (int i = 0; i < nbForwardDate; i++) {
     nodeTimesForward[i + 1] = timeForwardArray[i];
     yieldsForward[i + 1] = curveForward.getInterestRate(nodeTimesForward[i + 1]);
   }
   final YieldAndDiscountCurve tempCurveForward =
       new YieldCurve(
           InterpolatedDoublesCurve.fromSorted(
               nodeTimesForward, yieldsForward, new LinearInterpolator1D()));
   final List<DoublesPair> tempForward =
       pvsLongPayerExtra.getSensitivities().get(FORWARD_CURVE_NAME);
   final double[] resFwd = new double[nbForwardDate];
   for (int i = 0; i < nbForwardDate; i++) {
     final YieldAndDiscountCurve bumpedCurveForward =
         tempCurveForward.withSingleShift(nodeTimesForward[i + 1], deltaShift);
     final YieldCurveBundle curvesBumpedForward = new YieldCurveBundle();
     curvesBumpedForward.addAll(curves);
     curvesBumpedForward.setCurve("Bumped Curve", bumpedCurveForward);
     final SABRInterestRateDataBundle sabrBundleBumped =
         new SABRInterestRateDataBundle(sabrParameter, curvesBumpedForward);
     final double bumpedpv = methodExtra.presentValue(swaptionBumpedForward, sabrBundleBumped);
     resFwd[i] = (bumpedpv - pv) / deltaShift;
     final DoublesPair pair = tempForward.get(i);
     assertEquals(
         "Sensitivity to forward curve: Node " + i,
         nodeTimesForward[i + 1],
         pair.getFirst(),
         1E-8);
     assertEquals(
         "Sensitivity to forward curve: Node " + i, resFwd[i], pair.getSecond(), deltaTolerance);
   }
   // 2. Funding curve sensitivity
   final String[] bumpedCurvesFundingName = {bumpedCurveName, FORWARD_CURVE_NAME};
   final SwaptionCashFixedIbor swaptionBumpedFunding =
       swaptionDefinitionLongPayerHighStrike.toDerivative(REFERENCE_DATE, bumpedCurvesFundingName);
   final int nbPayDate =
       swaptionDefinitionLongPayerHighStrike.getUnderlyingSwap().getIborLeg().getPayments().length;
   final YieldAndDiscountCurve curveFunding = curves.getCurve(FUNDING_CURVE_NAME);
   final double[] yieldsFunding = new double[nbPayDate + 2];
   final double[] nodeTimesFunding = new double[nbPayDate + 2];
   yieldsFunding[0] = curveFunding.getInterestRate(0.0);
   nodeTimesFunding[1] = swaptionLongPayerHighStrike.getSettlementTime();
   yieldsFunding[1] = curveFunding.getInterestRate(nodeTimesFunding[1]);
   for (int i = 0; i < nbPayDate; i++) {
     nodeTimesFunding[i + 2] =
         swaptionLongPayerHighStrike
             .getUnderlyingSwap()
             .getSecondLeg()
             .getNthPayment(i)
             .getPaymentTime();
     yieldsFunding[i + 2] = curveFunding.getInterestRate(nodeTimesFunding[i + 2]);
   }
   final YieldAndDiscountCurve tempCurveFunding =
       new YieldCurve(
           InterpolatedDoublesCurve.fromSorted(
               nodeTimesFunding, yieldsFunding, new LinearInterpolator1D()));
   final List<DoublesPair> tempFunding =
       pvsLongPayerExtra.getSensitivities().get(FUNDING_CURVE_NAME);
   final double[] resDsc = new double[nbPayDate];
   for (int i = 0; i < nbPayDate; i++) {
     final YieldAndDiscountCurve bumpedCurve =
         tempCurveFunding.withSingleShift(nodeTimesFunding[i + 1], deltaShift);
     final YieldCurveBundle curvesBumped = new YieldCurveBundle();
     curvesBumped.addAll(curves);
     curvesBumped.setCurve("Bumped Curve", bumpedCurve);
     final SABRInterestRateDataBundle sabrBundleBumped =
         new SABRInterestRateDataBundle(sabrParameter, curvesBumped);
     final double bumpedpv = methodExtra.presentValue(swaptionBumpedFunding, sabrBundleBumped);
     resDsc[i] = (bumpedpv - pv) / deltaShift;
     final DoublesPair pair = tempFunding.get(i);
     assertEquals(
         "Sensitivity to discounting curve: Node " + i,
         nodeTimesFunding[i + 1],
         pair.getFirst(),
         1E-8);
     assertEquals(
         "Sensitivity to discounting curve: Node " + i,
         resDsc[i],
         pair.getSecond(),
         deltaTolerance);
   }
 }