QuantLib.jl

This package aims to provide a pure Julia version of the popular open source library QuantLib (written in C++ and interfaced with other languages via SWIG). Right now the package is in an alpha state, but there is quite a bit of functionality already.

Install

using Pkg; Pkg.add("QuantLib")

Note: only supports versions of Julia 1.0 and up

The package essentially contains the main QuantLib module and two sub-modules for various time-based and math-based operations. Below is a fairly up-to-date status of what is included.

Documentation: http://quantlibjl.readthedocs.org/en/latest/

Math

Interpolations:

Backward Flat
Linear
Log Linear
Cubic Spline
BiCubic Spline (implemented with Dierckx)

Optimization methods:

Simplex
Levenberg Marquardt

Solvers:

Brent
Finite Differences
Newton

Time

Calendars (adopted from BusinessDays.jl and Ito.jl):

Target (basically a null calendar with basic holidays)
US Settlement Calendar
US NYSE Calendar
US NERC Calendar
UK Settlement Calendar
UK LSE Calendar
UK LME Calendar

Day Counters:

Actual 360
Actual 365
Bond Thirty 360
Euro Bond Thirty 360
ISMA Actual
ISDA Actual
AFBA Actual

Instruments

Bonds:

Fixed Rate Bond
Floating Rate Bond

Options:

Vanilla Option
Swaption
Nonstandard Swaption (used for Gaussian methods)

Swaps:

Vanilla Swap
Nonstandard Swap (used for Gaussian methods)
Credit Default Swap (partial)

Indexes

Ibor
Libor
Euribor
USD Libor
Euribor Swap ISDA

Methods

Finite Differences
Trinomial Tree
Tree Lattice 1D & 2D
Monte Carlo

Models

Short Rate:

Black Karasinski
Gaussian Short Rate (GSR)
Hull White
G2

Equity:

Bates Model
Heston Model

Market Models

Flat Vol

Pricing Engines

Bond:

Discounting Bond Engine
Tree Callable Fixed Rate Bond Engine
Black Callable Fixed Rate Bond Engine

Swap:

Discounting Swap Engine

Credit:

MidPoint CDS Engine

Swaptions:

Black Swaption Engine
Finite Differences Hull White Pricing Engine
Finite Differences G2 Pricing Engine
G2 Swaption Engine
Gaussian 1D Nonstandard Swaption Engine
Gaussian 1D Swaption Engine
Jamshidian Swaption Engine
Tree Swaption Engine

Vanilla:

Analytic European Engine (for black scholes)
Analytic Heston Engine
Barone Adesi Whaley Engine
Bates Engine
Binomial Engine
Bjerksund Stensland Approximation Engine
FD Vanilla Engine
Integral Engine
MonteCarlo American Engine
MonteCarlo European Engine

General:

Black Scholes Calculator
Black Formula
MonteCarlo Simulation
Lattice ShortRate Model Engine

Processes

Black Scholes Process
Ornstein Uhlenbeck Process
Gaussian Short Rate Process
Bates Process
Heston Process

Term Structures

Credit:

Piecewise Default Curve
Interpolated Hazard Rate Curve

Volatility:

Black Constant Vol
Constant Optionlet Volatility
Constant Swaption Volatility
Local Constant Vol

Yield:

Flat Forward
Fitted Bond Curve (various fitting methods)
Piecewise Yield Curve
Discount Curve

Example

Price a fixed rate Bond

using QuantLib
using Dates

settlement_date = Date(2008, 9, 18) # construct settlement date
# settings is a global singleton that contains global settings
set_eval_date!(settings, settlement_date - Dates.Day(3))

# settings that we will need to construct the yield curve
freq = QuantLib.Time.Semiannual()
tenor = QuantLib.Time.TenorPeriod(freq)
conv = QuantLib.Time.Unadjusted()
conv_depo = QuantLib.Time.ModifiedFollowing()
rule = QuantLib.Time.DateGenerationBackwards()
calendar = QuantLib.Time.USGovernmentBondCalendar()
dc_depo = QuantLib.Time.Actual365()
dc = QuantLib.Time.ISDAActualActual()
dc_bond = QuantLib.Time.ISMAActualActual()
fixing_days = 3

# build depos
depo_rates = [0.0096, 0.0145, 0.0194]
depo_tens = [Dates.Month(3), Dates.Month(6), Dates.Month(12)]

# build bonds
issue_dates = [Date(2005, 3, 15), Date(2005, 6, 15), Date(2006, 6, 30), Date(2002, 11, 15),
              Date(1987, 5, 15)]
mat_dates = [Date(2010, 8, 31), Date(2011, 8, 31), Date(2013, 8, 31), Date(2018, 8, 15),
            Date(2038, 5, 15)]

coupon_rates = [0.02375, 0.04625, 0.03125, 0.04000, 0.04500]
market_quotes = [100.390625, 106.21875, 100.59375, 101.6875, 102.140625]

# construct the deposit and fixed rate bond helpers
insts = Vector{BootstrapHelper}(undef, length(depo_rates) + length(issue_dates))
for i = 1:length(depo_rates)
  depo_quote = Quote(depo_rates[i])
  depo_tenor = QuantLib.Time.TenorPeriod(depo_tens[i])
  depo = DepositRateHelper(depo_quote, depo_tenor, fixing_days, calendar, conv_depo, true, dc_depo)
  insts[i] = depo
end

for i =1:length(coupon_rates)
  term_date = mat_dates[i]
  rate = coupon_rates[i]
  issue_date = issue_dates[i]
  market_quote = market_quotes[i]
  sched = QuantLib.Time.Schedule(issue_date, term_date, tenor, conv, conv, rule, true)
  bond = FixedRateBondHelper(Quote(market_quote), FixedRateBond(3, 100.0, sched, rate, dc_bond, conv,
                            100.0, issue_date, calendar, DiscountingBondEngine()))
  insts[i + length(depo_rates)] = bond
end

# Construct the Yield Curve
interp = QuantLib.Math.LogLinear()
trait = Discount()
bootstrap = IterativeBootstrap()
yts = PiecewiseYieldCurve(settlement_date, insts, dc, interp, trait, 0.00000000001, bootstrap)

# Build it
calculate!(yts)

# Build our Fixed Rate Bond
settlement_days = 3
face_amount = 100.0

fixed_schedule = QuantLib.Time.Schedule(Date(2007, 5, 15), Date(2017, 5, 15),
                QuantLib.Time.TenorPeriod(QuantLib.Time.Semiannual()), QuantLib.Time.Unadjusted(),
                QuantLib.Time.Unadjusted(), QuantLib.Time.DateGenerationBackwards(), false,
                QuantLib.Time.USGovernmentBondCalendar())

pe = DiscountingBondEngine(yts)

fixedrate_bond = FixedRateBond(settlement_days, face_amount, fixed_schedule, 0.045,
                  QuantLib.Time.ISMAActualActual(), QuantLib.Time.ModifiedFollowing(), 100.0,
                  Date(2007, 5, 15), fixed_schedule.cal, pe)

# Calculate NPV
npv(fixedrate_bond) # 107.66828913260542

bv441 / quantlib.jl Goto Github PK

quantlib.jl's Introduction

QuantLib.jl

Install

Math

Time

Instruments

Indexes

Methods

Models

Pricing Engines

Processes

Term Structures

Example

Price a fixed rate Bond

quantlib.jl's People

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