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RBC_CPP_2.cpp
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RBC_CPP_2.cpp
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//============================================================================
// Name : RBC_CPP.cpp
// Description : Basic RBC model with full depreciation, more idiomatic C++ version
// Date : July 21, 2013
// Corrected by: Dziubinski, Matt P, [email protected]
//============================================================================
#include <array>
#include <chrono> // time measurement
#include <cmath> // std::abs, std::log, std::pow
#include <cstddef> // std::size_t
#include <iostream>
#include <limits> // std::numeric_limits
// fixed-size vector, size: Rows
template <std::size_t Rows> using Vector = std::array<double, Rows>;
// fixed-size matrix, size: Rows * Columns
template <std::size_t Rows, std::size_t Columns> using Matrix = std::array<Vector<Columns>, Rows>;
int main()
{
const auto time_0 = std::chrono::steady_clock::now();
///////////////////////////////////////////////////////////////////////////////////////////
// 1. Calibration
///////////////////////////////////////////////////////////////////////////////////////////
const auto aalpha = 1. / 3.; // Elasticity of output w.r.t. capital
const auto bbeta = 0.95; // Discount factor;
// Productivity values
const std::size_t nGridProductivity = 5;
const Vector<nGridProductivity> vProductivity{ { 0.9792, 0.9896, 1.0000, 1.0106, 1.0212 } };
// Transition matrix
const Matrix<nGridProductivity, nGridProductivity> mTransition{ {
{ 0.9727, 0.0273, 0.0000, 0.0000, 0.0000 },
{ 0.0041, 0.9806, 0.0153, 0.0000, 0.0000 },
{ 0.0000, 0.0082, 0.9837, 0.0082, 0.0000 },
{ 0.0000, 0.0000, 0.0153, 0.9806, 0.0041 },
{ 0.0000, 0.0000, 0.0000, 0.0273, 0.9727 }
} };
///////////////////////////////////////////////////////////////////////////////////////////
// 2. Steady State
///////////////////////////////////////////////////////////////////////////////////////////
const auto capitalSteadyState = std::pow(aalpha * bbeta, 1. / (1. - aalpha));
const auto outputSteadyState = std::pow(capitalSteadyState, aalpha);
const auto consumptionSteadyState = outputSteadyState - capitalSteadyState;
std::cout << "Output = " << outputSteadyState << ", Capital = " << capitalSteadyState << ", Consumption = " << consumptionSteadyState << "\n";
// We generate the grid of capital
const std::size_t nGridCapital = 17820;
Vector<nGridCapital> vGridCapital;
for (std::size_t nCapital = 0; nCapital < nGridCapital; ++nCapital)
vGridCapital[nCapital] = 0.5 * capitalSteadyState + 0.00001 * nCapital;
// 3. Required matrices and vectors
Matrix<nGridCapital, nGridProductivity> mOutput; // default-initialization (indeterminate value)
Matrix<nGridCapital, nGridProductivity> mValueFunction = {}; // value-initialization
Matrix<nGridCapital, nGridProductivity> mValueFunctionNew = {}; // value-initialization
Matrix<nGridCapital, nGridProductivity> mPolicyFunction = {}; // value-initialization
Matrix<nGridCapital, nGridProductivity> expectedValueFunction; // default-initialization (indeterminate value)
// 4. We pre-build output for each point in the grid
for (std::size_t nProductivity = 0; nProductivity < nGridProductivity; ++nProductivity)
{
for (std::size_t nCapital = 0; nCapital < nGridCapital; ++nCapital)
mOutput[nCapital][nProductivity] = vProductivity[nProductivity] * std::pow(vGridCapital[nCapital], aalpha);
}
// 5. Main iteration
const double tolerance = 0.0000001;
auto maxDifference = 10.0;
std::size_t iteration = 0;
while (maxDifference > tolerance)
{
for (std::size_t nProductivity = 0; nProductivity < nGridProductivity; ++nProductivity)
{
for (std::size_t nCapital = 0; nCapital < nGridCapital; ++nCapital)
{
expectedValueFunction[nCapital][nProductivity] = 0.0;
for (std::size_t nProductivityNextPeriod = 0; nProductivityNextPeriod < nGridProductivity; ++nProductivityNextPeriod)
expectedValueFunction[nCapital][nProductivity] += mTransition[nProductivity][nProductivityNextPeriod] * mValueFunction[nCapital][nProductivityNextPeriod];
}
}
for (std::size_t nProductivity = 0; nProductivity < nGridProductivity; ++nProductivity)
{
// We start from previous choice (monotonicity of policy function)
std::size_t gridCapitalNextPeriod = 0;
for (std::size_t nCapital = 0; nCapital < nGridCapital; ++nCapital)
{
auto valueHighSoFar = -std::numeric_limits<double>::infinity();
auto capitalChoice = vGridCapital[0];
for (std::size_t nCapitalNextPeriod = gridCapitalNextPeriod; nCapitalNextPeriod < nGridCapital; ++nCapitalNextPeriod)
{
const auto consumption = mOutput[nCapital][nProductivity] - vGridCapital[nCapitalNextPeriod];
const auto valueProvisional = (1. - bbeta) * std::log(consumption) + bbeta * expectedValueFunction[nCapitalNextPeriod][nProductivity];
if (valueProvisional > valueHighSoFar)
{
valueHighSoFar = valueProvisional;
capitalChoice = vGridCapital[nCapitalNextPeriod];
gridCapitalNextPeriod = nCapitalNextPeriod;
}
else
{
mValueFunctionNew[nCapital][nProductivity] = valueHighSoFar;
mPolicyFunction[nCapital][nProductivity] = capitalChoice;
// We break when we have achieved the max (note: of a monotonic function)
break;
}
mValueFunctionNew[nCapital][nProductivity] = valueHighSoFar;
mPolicyFunction[nCapital][nProductivity] = capitalChoice;
}
}
}
double diffHighSoFar = -std::numeric_limits<double>::infinity();
for (std::size_t nProductivity = 0; nProductivity < nGridProductivity; ++nProductivity)
{
for (std::size_t nCapital = 0; nCapital<nGridCapital; ++nCapital)
{
const auto diff = std::abs(mValueFunction[nCapital][nProductivity] - mValueFunctionNew[nCapital][nProductivity]);
if (diff > diffHighSoFar) diffHighSoFar = diff;
mValueFunction[nCapital][nProductivity] = mValueFunctionNew[nCapital][nProductivity];
}
}
maxDifference = diffHighSoFar;
++iteration;
if ((iteration % 10 == 0) || (iteration == 1))
std::cout << "Iteration = " << iteration << ", Sup Diff = " << maxDifference << "\n";
}
std::cout << "Iteration = " << iteration << ", Sup Diff = " << maxDifference << "\n";
endl(std::cout);
std::cout << "My check = " << mPolicyFunction[999][2] << "\n";
endl(std::cout);
const auto time_1 = std::chrono::steady_clock::now();
const auto elapsed_seconds = std::chrono::duration_cast<std::chrono::duration<double>>(time_1 - time_0).count();
std::cout << "Elapsed time is = " << elapsed_seconds << " seconds." << std::endl;
endl(std::cout);
return 0;
}