@Override
 public double[] getNodeSensitivitiesForValue(Interpolator1DDataBundle data, Double value) {
   ArgChecker.notNull(value, "Value to be interpolated must not be null");
   ArgChecker.notNull(data, "Data bundle must not be null");
   int n = data.size();
   double[] resultSensitivity = new double[n];
   InterpolationBoundedValues boundedValues = data.getBoundedValues(value);
   double x1 = boundedValues.getLowerBoundKey();
   double y1 = boundedValues.getLowerBoundValue();
   int index = boundedValues.getLowerBoundIndex();
   if (index == n - 1) {
     resultSensitivity[n - 1] = 1.0;
     return resultSensitivity;
   }
   double x2 = boundedValues.getHigherBoundKey();
   double y2 = boundedValues.getHigherBoundValue();
   if ((y1 < EPS) || (y2 < EPS)) {
     throw new UnsupportedOperationException(
         "node sensitivity not implemented when one node is 0 value");
   }
   double w = (x2 - value) / (x2 - x1);
   double xy21 = x1 * y1 * y1;
   double xy22 = x2 * y2 * y2;
   double xy2 = w * xy21 + (1 - w) * xy22;
   double resultValue = Math.sqrt(xy2 / value);
   double resultValueBar = 1.0;
   double xy2Bar = 0.5 / resultValue / value * resultValueBar;
   double xy21Bar = w * xy2Bar;
   double xy22Bar = (1 - w) * xy2Bar;
   double y2Bar = 2 * x2 * y2 * xy22Bar;
   double y1Bar = 2 * x1 * y1 * xy21Bar;
   resultSensitivity[index] = y1Bar;
   resultSensitivity[index + 1] = y2Bar;
   return resultSensitivity;
 }
Example #2
0
  /**
   * Make a set of standard CDS represented as a MultiCdsAnalytic instance. The maturities of the
   * CDS are measured from the next IMM date (after the trade date), and the tenors are the given
   * matIndices multiplied by the coupon interval (3 months).
   *
   * @param tradeDate the trade date
   * @param accStartDate the accrual start date
   * @param matIndices the CDS tenors are these multiplied by the coupon interval (3 months)
   * @return a set of CDS represented as a MultiCdsAnalytic
   */
  public MultiCdsAnalytic makeMultiImmCds(
      LocalDate tradeDate, LocalDate accStartDate, int[] matIndices) {
    if (!_couponInterval.equals(DEFAULT_COUPON_INT)) {
      throw new IllegalArgumentException(
          "coupon interval must be 3M for this method. However it is set to "
              + _couponInterval.toString());
    }
    ArgChecker.notNull(tradeDate, "tradeDate");
    ArgChecker.notEmpty(matIndices, "matIndicies");

    LocalDate nextIMM = ImmDateLogic.getNextIMMDate(tradeDate);
    LocalDate stepinDate = tradeDate.plusDays(_stepIn);
    LocalDate valueDate = addWorkDays(tradeDate, _cashSettle, _calendar);

    return new MultiCdsAnalytic(
        tradeDate,
        stepinDate,
        valueDate,
        accStartDate,
        nextIMM,
        matIndices,
        _payAccOnDefault,
        _couponIntervalTenor,
        _stubType,
        _protectStart,
        _recoveryRate,
        _businessdayAdjustmentConvention,
        DEFAULT_CALENDAR,
        _accrualDayCount,
        _curveDayCount);
  }
Example #3
0
 /**
  * Creates a periodic frequency.
  *
  * @param period the period to represent
  * @param name the name
  */
 private Frequency(Period period, String name) {
   ArgChecker.notNull(period, "period");
   ArgChecker.isFalse(period.isZero(), "Period must not be zero");
   ArgChecker.isFalse(period.isNegative(), "Period must not be negative");
   this.period = period;
   this.name = name;
 }
 // -------------------------------------------------------------------------
 @Override
 public double getVolatility(DoubleArray t) {
   ArgChecker.notNull(t, "data");
   ArgChecker.isTrue(
       t.size() == 4, "data should have four components (expiry time, tenor, strike and forward");
   return getVolatility(t.get(0), t.get(1), t.get(2), t.get(3));
 }
  @Override
  public MulticurveSensitivity visitSwapFuturesPriceDeliverableSecurity(
      final SwapFuturesPriceDeliverableSecurity futures,
      final ParameterProviderInterface multicurve) {
    ArgChecker.notNull(futures, "futures");
    ArgChecker.notNull(multicurve, "multi-curve provider");
    double dfInv =
        1.0
            / multicurve
                .getMulticurveProvider()
                .getDiscountFactor(futures.getCurrency(), futures.getDeliveryTime());
    MulticurveSensitivity pvcs =
        futures
            .getUnderlyingSwap()
            .accept(PVCSDC, multicurve.getMulticurveProvider())
            .getSensitivity(futures.getCurrency())
            .multipliedBy(dfInv);

    final PresentValueDiscountingCalculator pvCalc =
        PresentValueDiscountingCalculator.getInstance();
    double pv =
        futures
            .getUnderlyingSwap()
            .accept(pvCalc, multicurve.getMulticurveProvider())
            .getAmount(futures.getCurrency())
            .getAmount();
    final Map<String, List<DoublesPair>> resultMap = new HashMap<>();
    final List<DoublesPair> listDf = new ArrayList<>();
    listDf.add(DoublesPair.of(futures.getDeliveryTime(), futures.getDeliveryTime() * pv * dfInv));
    resultMap.put(multicurve.getMulticurveProvider().getName(futures.getCurrency()), listDf);
    MulticurveSensitivity result = MulticurveSensitivity.ofYieldDiscounting(resultMap);
    return result.plus(pvcs);
  }
Example #6
0
  /**
   * Solves the system Ax = y for the unknown vector x, where A is a tridiagonal matrix and y is a
   * vector. This takes order n operations where n is the size of the system (number of linear
   * equations), as opposed to order n^3 for the general problem.
   *
   * @param aM tridiagonal matrix
   * @param b known vector (must be same length as rows/columns of matrix)
   * @return vector (as an array of doubles) with same length as y
   */
  public static double[] solvTriDag(TridiagonalMatrix aM, double[] b) {

    ArgChecker.notNull(aM, "null matrix");
    ArgChecker.notNull(b, "null vector");
    double[] d = aM.getDiagonal(); // b is modified, so get copy of diagonal
    int n = d.length;
    ArgChecker.isTrue(n == b.length, "vector y wrong length for matrix");
    double[] y = Arrays.copyOf(b, n);

    double[] l = aM.getLowerSubDiagonalData();
    double[] u = aM.getUpperSubDiagonalData();

    double[] x = new double[n];
    for (int i = 1; i < n; i++) {
      double m = l[i - 1] / d[i - 1];
      d[i] = d[i] - m * u[i - 1];
      y[i] = y[i] - m * y[i - 1];
    }

    x[n - 1] = y[n - 1] / d[n - 1];

    for (int i = n - 2; i >= 0; i--) {
      x[i] = (y[i] - u[i] * x[i + 1]) / d[i];
    }

    return x;
  }
  @Override
  public GreekResultCollection visitEquityOption(
      final EquityOption option, final StaticReplicationDataBundle data) {
    ArgChecker.notNull(option, "option");
    ArgChecker.notNull(data, "data");
    final double k = option.getStrike();
    final double t = option.getTimeToExpiry();
    final boolean isCall = option.isCall();
    final double volatility = data.getVolatilitySurface().getVolatility(t, k);
    final double r = data.getDiscountCurve().getInterestRate(t);
    final double spot = data.getForwardCurve().getSpot();
    final double fwd = data.getForwardCurve().getForward(t);
    final double b;
    if (t > 0) {
      b = Math.log(fwd / spot) / t;
    } else {
      b = r; // TODO
    }
    final double[] greeks = MODEL.getPriceAdjoint(spot, k, r, b, t, volatility, isCall);
    final GreekResultCollection result = new GreekResultCollection();
    result.put(Greek.DELTA, greeks[1]);
    result.put(Greek.DUAL_DELTA, greeks[2]);
    result.put(Greek.RHO, greeks[3]);
    result.put(Greek.CARRY_RHO, greeks[4]);
    result.put(Greek.THETA, greeks[5]);
    result.put(Greek.VEGA, greeks[6]);

    final double[] pdg = MODEL.getPriceDeltaGamma(spot, k, r, b, t, volatility, isCall);
    result.put(Greek.GAMMA, pdg[2]);
    return result;
  }
 /**
  * @param baseInterpolator The interpolator used for interpolating in the transformed space
  * @param transform a two way mapping between a limited range and the real line
  */
 public TransformedInterpolator1D(
     final Interpolator1D baseInterpolator, final ParameterLimitsTransform transform) {
   ArgChecker.notNull(baseInterpolator, "null baseInterpolator");
   ArgChecker.notNull(transform, "null transform");
   _base = baseInterpolator;
   _transform = transform;
 }
 /**
  * Merges the specified date/value point into this builder.
  *
  * <p>The operator is invoked if the date already exists.
  *
  * @param date the date to be added
  * @param value the value associated with the date
  * @param operator the operator to use for merging
  * @return this builder
  */
 public LocalDateDoubleTimeSeriesBuilder merge(
     LocalDate date, double value, DoubleBinaryOperator operator) {
   ArgChecker.notNull(date, "date");
   ArgChecker.notNull(operator, "operator");
   entries.merge(date, value, (a, b) -> operator.applyAsDouble(a, b));
   return this;
 }
 private SurfaceMetadata updateSurfaceMetadata(Set<DoublesPair> pairs) {
   SurfaceMetadata surfaceMetadata = surface.getMetadata();
   List<SurfaceParameterMetadata> sortedMetaList = new ArrayList<SurfaceParameterMetadata>();
   if (surfaceMetadata.getParameterMetadata().isPresent()) {
     List<SurfaceParameterMetadata> metaList =
         new ArrayList<SurfaceParameterMetadata>(surfaceMetadata.getParameterMetadata().get());
     for (DoublesPair pair : pairs) {
       metadataLoop:
       for (SurfaceParameterMetadata parameterMetadata : metaList) {
         ArgChecker.isTrue(
             parameterMetadata instanceof GenericVolatilitySurfaceYearFractionMetadata,
             "Surface parameter metadata must be instance of GenericVolatilitySurfaceYearFractionMetadata");
         GenericVolatilitySurfaceYearFractionMetadata casted =
             (GenericVolatilitySurfaceYearFractionMetadata) parameterMetadata;
         if (pair.getFirst() == casted.getYearFraction()
             && pair.getSecond() == casted.getStrike().getValue()) {
           sortedMetaList.add(casted);
           metaList.remove(parameterMetadata);
           break metadataLoop;
         }
       }
     }
     ArgChecker.isTrue(
         metaList.size() == 0,
         "Mismatch between surface parameter metadata list and doubles pair list");
   } else {
     for (DoublesPair pair : pairs) {
       GenericVolatilitySurfaceYearFractionMetadata parameterMetadata =
           GenericVolatilitySurfaceYearFractionMetadata.of(
               pair.getFirst(), SimpleStrike.of(pair.getSecond()));
       sortedMetaList.add(parameterMetadata);
     }
   }
   return surfaceMetadata.withParameterMetadata(sortedMetaList);
 }
 public BasisFunctionAggregation(List<Function<T, Double>> functions, double[] weights) {
   ArgChecker.notEmpty(functions, "no functions");
   ArgChecker.notNull(weights, "no weights");
   ArgChecker.isTrue(functions.size() == weights.length);
   _f = functions;
   _w = weights.clone();
 }
Example #12
0
 /**
  * Make a set of CDSs with a common trade date and maturities dates the given periods after the
  * next IMM date (after the trade-date).
  *
  * @param tradeDate the trade date
  * @param accStartDate this is when the CDS nominally starts in terms of premium payments. For a
  *     standard CDS this is the previous IMM date, and for a `legacy' CDS it is T+1
  * @param tenors the tenors (lengths) of the CDSs
  * @return an array of CDS analytic descriptions
  */
 public CdsAnalytic[] makeImmCds(LocalDate tradeDate, LocalDate accStartDate, Period[] tenors) {
   ArgChecker.notNull(tradeDate, "tradeDate");
   ArgChecker.notNull(accStartDate, "effectiveDate");
   ArgChecker.noNulls(tenors, "tenors");
   LocalDate nextIMM = ImmDateLogic.getNextIMMDate(tradeDate);
   LocalDate[] maturities = ImmDateLogic.getIMMDateSet(nextIMM, tenors);
   return makeCds(tradeDate, accStartDate, maturities);
 }
  /**
   * Constructor from a multicurveSensitivity and a sensitivityPriceCurve. The maps are used
   * directly.
   *
   * @param multicurveSensitivity The multicurveSensitivity.
   * @param sensitivityCommodityForwardCurve The map.
   * @return The sensitivity.
   */
  public static CommoditySensitivity of(
      final MulticurveSensitivity multicurveSensitivity,
      final Map<String, List<DoublesPair>> sensitivityCommodityForwardCurve) {

    ArgChecker.notNull(multicurveSensitivity, "multicurve sensitivity");
    ArgChecker.notNull(sensitivityCommodityForwardCurve, "Sensitivity commodity forward curve");
    return new CommoditySensitivity(multicurveSensitivity, sensitivityCommodityForwardCurve);
  }
Example #14
0
 /**
  * Set up a strip of on-the-run indexes represented as a single name CDSs (i.e. by CdsAnalytic).
  * The index roll dates (when new indices are issued) are 20 Mar & Sep, and the index is defined
  * to have a maturity that is its nominal tenor plus 3M on issuance, so a 5Y index on the
  * 6-Feb-2014 will have a maturity of 20-Dec-2018 (5Y3M on the issue date of 20-Sep-2013). The
  * accrual start date will be the previous IMM date (before the trade date), business-day
  * adjusted. <b>Note</b> it payment interval is changed from the default of 3M, this will produce
  * a (possibly incorrect) non-standard first coupon.
  *
  * @param tradeDate the trade date
  * @param tenors the nominal lengths of the indexes
  * @return an array of CDS analytic descriptions
  */
 public CdsAnalytic[] makeCdx(LocalDate tradeDate, Period[] tenors) {
   ArgChecker.notNull(tradeDate, "tradeDate");
   ArgChecker.noNulls(tenors, "tenors");
   LocalDate effectiveDate =
       _businessdayAdjustmentConvention.adjust(ImmDateLogic.getPrevIMMDate(tradeDate), _calendar);
   LocalDate mid = ImmDateLogic.getNextIndexRollDate(tradeDate).minusMonths(3);
   LocalDate[] maturities = ImmDateLogic.getIMMDateSet(mid, tenors);
   return makeCds(tradeDate, effectiveDate, maturities);
 }
 /**
  * Puts the specified date/value point into this builder.
  *
  * @param date the date to be added
  * @param value the value associated with the date
  * @return this builder
  */
 public LocalDateDoubleTimeSeriesBuilder put(LocalDate date, double value) {
   ArgChecker.notNull(date, "date");
   ArgChecker.isFalse(Double.isNaN(value), "NaN is not allowed as a value");
   entries.put(date, value);
   if (!containsWeekends && date.get(ChronoField.DAY_OF_WEEK) > 5) {
     containsWeekends = true;
   }
   return this;
 }
 // -------------------------------------------------------------------------
 @ImmutableValidator
 private void validate() {
   if (rebate != null) {
     ArgChecker.isTrue(rebate.getAmount() > 0d, "rebate must be positive");
     ArgChecker.isTrue(
         underlyingOption.getUnderlying().getCurrencyPair().contains(rebate.getCurrency()),
         "The rebate currency must be one of underlying currency pair");
   }
 }
 @Override
 public Interpolator1DDataBundle getDataBundleFromSortedArrays(double[] x, double[] y) {
   ArgChecker.notNull(y, "y");
   int nY = y.length;
   for (int i = 0; i < nY; ++i) {
     ArgChecker.isTrue(y[i] >= 0.0, "All values in y must be positive");
   }
   return new ArrayInterpolator1DDataBundle(x, y, true);
 }
Example #18
0
 /**
  * Set up an on-the-run index represented as a single name CDS (i.e. by CdsAnalytic). The index
  * roll dates (when new indices are issued) are 20 Mar & Sep, and the index is defined to have a
  * maturity that is its nominal tenor plus 3M on issuance, so a 5Y index on the 6-Feb-2014 will
  * have a maturity of 20-Dec-2018 (5Y3M on the issue date of 20-Sep-2013). The accrual start date
  * will be the previous IMM date (before the trade date), business-day adjusted. <b>Note</b> it
  * payment interval is changed from the default of 3M, this will produce a (possibly incorrect)
  * non-standard first coupon.
  *
  * @param tradeDate the trade date
  * @param tenor the nominal length of the index
  * @return a CDS analytic description
  */
 public CdsAnalytic makeCdx(LocalDate tradeDate, Period tenor) {
   ArgChecker.notNull(tradeDate, "tradeDate");
   ArgChecker.notNull(tenor, "tenor");
   LocalDate effectiveDate =
       _businessdayAdjustmentConvention.adjust(ImmDateLogic.getPrevIMMDate(tradeDate), _calendar);
   LocalDate roll = ImmDateLogic.getNextIndexRollDate(tradeDate);
   LocalDate maturity = roll.plus(tenor).minusMonths(3);
   return makeCds(tradeDate, effectiveDate, maturity);
 }
 /**
  * Returns the convexity adjustment, i.e. the difference between the adjusted price and the
  * present value of the underlying swap.
  *
  * @param futures The swap futures.
  * @param hwMulticurves The multi-curve and parameters provider.
  * @return The adjustment.
  */
 public double convexityAdjustment(
     final SwapFuturesPriceDeliverableSecurity futures,
     final HullWhiteOneFactorProviderInterface hwMulticurves) {
   ArgChecker.notNull(futures, "swap futures");
   ArgChecker.notNull(hwMulticurves, "parameter provider");
   MultiCurrencyAmount pv =
       futures.getUnderlyingSwap().accept(PVDC, hwMulticurves.getMulticurveProvider());
   double price = price(futures, hwMulticurves);
   return price - (1.0d + pv.getAmount(futures.getCurrency()).getAmount());
 }
Example #20
0
 /**
  * Make a set of standard CDS represented as a MultiCdsAnalytic instance. The maturities of the
  * CDS are measured from the next IMM date (after the trade date), and the first and last tenors
  * are the firstIndex and lastIndex multiplied by the coupon interval (3 months), which the
  * remaining tenors being everything in between.
  *
  * @param tradeDate the trade date
  * @param firstIndex the First index
  * @param lastIndex the last index
  * @return a set of CDS represented as a MultiCdsAnalytic
  */
 public MultiCdsAnalytic makeMultiImmCds(LocalDate tradeDate, int firstIndex, int lastIndex) {
   ArgChecker.isTrue(lastIndex > firstIndex, "Require lastIndex>firstIndex");
   ArgChecker.isTrue(firstIndex >= 0, "Require positive indices");
   int n = lastIndex - firstIndex + 1;
   int[] matIndices = new int[n];
   for (int i = 0; i < n; i++) {
     matIndices[i] = i + firstIndex;
   }
   return makeMultiImmCds(tradeDate, matIndices);
 }
Example #21
0
 /**
  * Obtains a template based on the specified periods and convention.
  *
  * <p>The periods from the spot date to the start date and to the end date are specified.
  *
  * <p>For example, a '2 x 5' FRA has a period to the start date of 2 months and a period to the
  * end date of 5 months.
  *
  * @param periodToStart the period between the spot date and the start date
  * @param periodToEnd the period between the spot date and the end date
  * @param convention the market convention
  * @return the template
  */
 public static FraTemplate of(Period periodToStart, Period periodToEnd, FraConvention convention) {
   ArgChecker.notNull(periodToStart, "periodToStart");
   ArgChecker.notNull(periodToEnd, "periodToEnd");
   ArgChecker.notNull(convention, "convention");
   return FraTemplate.builder()
       .periodToStart(periodToStart)
       .periodToEnd(periodToEnd)
       .convention(convention)
       .build();
 }
 /**
  * Constructor from a yield discounting map of sensitivity. The maps are used directly.
  *
  * @param sensitivityYieldDiscounting The map.
  * @param sensitivityForward The map.
  * @param sensitivityCommodityForwardCurve The map.
  * @return The sensitivity.
  */
 public static CommoditySensitivity of(
     final Map<String, List<DoublesPair>> sensitivityYieldDiscounting,
     final Map<String, List<ForwardSensitivity>> sensitivityForward,
     final Map<String, List<DoublesPair>> sensitivityCommodityForwardCurve) {
   ArgChecker.notNull(sensitivityYieldDiscounting, "Sensitivity yield curve");
   ArgChecker.notNull(sensitivityForward, "Sensitivity forward");
   ArgChecker.notNull(sensitivityCommodityForwardCurve, "Sensitivity commodity forward curve");
   return new CommoditySensitivity(
       sensitivityYieldDiscounting, sensitivityForward, sensitivityCommodityForwardCurve);
 }
Example #23
0
 /**
  * Make a CDS with a maturity date the given period on from the next IMM date after the
  * trade-date. The accrual start date will be the previous IMM date (before the trade date).
  * <b>Note</b> it payment interval is changed from the default of 3M, this will produce a
  * (possibly incorrect) non-standard first coupon.
  *
  * @param tradeDate the trade date
  * @param tenor the tenor (length) of the CDS
  * @param makeEffBusDay is the accrual start day business-day adjusted.
  * @return a CDS analytic description
  */
 public CdsAnalytic makeImmCds(LocalDate tradeDate, Period tenor, boolean makeEffBusDay) {
   ArgChecker.notNull(tradeDate, "tradeDate");
   ArgChecker.notNull(tenor, "tenor");
   LocalDate effectiveDate =
       makeEffBusDay
           ? _businessdayAdjustmentConvention.adjust(
               ImmDateLogic.getPrevIMMDate(tradeDate), _calendar)
           : ImmDateLogic.getPrevIMMDate(tradeDate);
   LocalDate nextIMM = ImmDateLogic.getNextIMMDate(tradeDate);
   LocalDate maturity = nextIMM.plus(tenor);
   return makeCds(tradeDate, effectiveDate, maturity);
 }
  /**
   * @param spotValues Spot values
   * @return realized variance
   */
  public double getRealizedVariance(final double[] spotValues) {
    ArgChecker.notNull(spotValues, "spotValues");
    final int nSpots = spotValues.length;
    ArgChecker.isTrue(nSpots > 1, "Number of spot values should be greater than 1");

    double res = 0.0;
    for (int i = 1; i < nSpots; ++i) {
      res += Math.pow(Math.log(spotValues[i] / spotValues[i - 1]), 2.0);
    }
    final double factor = 252.0 * 1.e4 / (nSpots - 1.0);
    res *= factor;
    return res;
  }
 /**
  * Puts all the specified dates and values into this builder.
  *
  * <p>The date collection and value array must be the same size.
  *
  * <p>The date-value pairs are added one by one. If a date is duplicated it will overwrite an
  * earlier entry.
  *
  * @param dates the dates to be added
  * @param values the values to be added
  * @return this builder
  */
 public LocalDateDoubleTimeSeriesBuilder putAll(Collection<LocalDate> dates, double[] values) {
   ArgChecker.noNulls(dates, "dates");
   ArgChecker.notNull(values, "values");
   ArgChecker.isTrue(
       dates.size() == values.length,
       "Arrays are of different sizes - dates: {}, values: {}",
       dates.size(),
       values.length);
   Iterator<LocalDate> itDate = dates.iterator();
   for (int i = 0; i < dates.size(); i++) {
     put(itDate.next(), values[i]);
   }
   return this;
 }
Example #26
0
 /**
  * Make a set of standard CDS represented as a MultiCdsAnalytic instance. The first CDS with have
  * a tenor of firstTenor, while the last CDS will have a tenor of lastTenor; the remaining CDS
  * will consist of all the (multiple of 3 month) tenors between the first and last tenor, e.g. if
  * firstTenor = 6M and lastTenor = 5Y, there will be a total of 22 CDS with tenors of 6M, 9M,
  * 1Y,....4Y9M, 5Y.
  *
  * @param tradeDate the trade date
  * @param firstTenor the first tenor
  * @param lastTenor the last tenor
  * @return a set of CDS represented as a MultiCdsAnalytic
  */
 public MultiCdsAnalytic makeMultiImmCds(
     LocalDate tradeDate, Period firstTenor, Period lastTenor) {
   ArgChecker.notNull(firstTenor, "firstTenor");
   ArgChecker.notNull(lastTenor, "lastTenor");
   int immNMonths = (int) DEFAULT_COUPON_INT.toTotalMonths();
   int m1 = (int) firstTenor.toTotalMonths();
   int m2 = (int) lastTenor.toTotalMonths();
   if (m1 % immNMonths != 0 || m2 % immNMonths != 0) {
     throw new IllegalArgumentException(
         "tenors is not a multiple of " + DEFAULT_COUPON_INT.toString());
   }
   int firstIndex = m1 / immNMonths;
   int lastIndex = m2 / immNMonths;
   return makeMultiImmCds(tradeDate, firstIndex, lastIndex);
 }
 /**
  * Simpson's integration method.
  *
  * <p>Note that the Commons implementation fails if the lower bound is larger than the upper - in
  * this case, the bounds are reversed and the result negated.
  *
  * @param f The function to integrate, not null
  * @param lower The lower bound, not null
  * @param upper The upper bound, not null
  * @return The result of the integration
  */
 @Override
 public Double integrate(Function<Double, Double> f, Double lower, Double upper) {
   ArgChecker.notNull(f, "function");
   ArgChecker.notNull(lower, "lower bound");
   ArgChecker.notNull(upper, "upper bound");
   try {
     if (lower < upper) {
       return integrator.integrate(MAX_EVAL, CommonsMathWrapper.wrapUnivariate(f), lower, upper);
     }
     log.info("Upper bound was less than lower bound; swapping bounds and negating result");
     return -integrator.integrate(MAX_EVAL, CommonsMathWrapper.wrapUnivariate(f), upper, lower);
   } catch (NumberIsTooSmallException | NumberIsTooLargeException e) {
     throw new MathException(e);
   }
 }
Example #28
0
  /**
   * Add a certain number of working days (defined by the holidayCalendar) to a date.
   *
   * @param startDate the start date
   * @param workingDaysToAdd working days to add
   * @param calendar the calendar of holidays
   * @return a working day
   */
  private static LocalDate addWorkDays(
      LocalDate startDate, int workingDaysToAdd, HolidayCalendar calendar) {
    ArgChecker.notNull(startDate, "startDate");
    ArgChecker.notNull(calendar, "calendar");

    int daysLeft = workingDaysToAdd;
    LocalDate temp = startDate;
    while (daysLeft > 0) {
      temp = temp.plusDays(1);
      if (calendar.isBusinessDay(temp)) {
        daysLeft--;
      }
    }
    return temp;
  }
 // -------------------------------------------------------------------------
 @Override
 public double relativeTime(ZonedDateTime dateTime) {
   ArgChecker.notNull(dateTime, "dateTime");
   LocalDate valuationDate = valuationDateTime.toLocalDate();
   LocalDate date = dateTime.toLocalDate();
   return dayCount.relativeYearFraction(valuationDate, date);
 }
 /**
  * Constructor from LMM parameters and curve bundle.
  *
  * @param lmmParameters The LMM model parameters.
  * @param curves Curve bundle.
  */
 public LiborMarketModelDisplacedDiffusionDataBundle(
     final LiborMarketModelDisplacedDiffusionParameters lmmParameters,
     final YieldCurveBundle curves) {
   super(curves);
   ArgChecker.notNull(lmmParameters, "LMM parameters");
   _parameters = lmmParameters;
 }