X-Git-Url: http://git.treefish.org/~alex/seamulator.git/blobdiff_plain/94e405360849659ff951816a13cf510f11a7eee7..f2e44f70d56b60e6eef78656ca4b558917474276:/sea.cpp?ds=inline diff --git a/sea.cpp b/sea.cpp index 37a6cd6..85191d4 100644 --- a/sea.cpp +++ b/sea.cpp @@ -1,17 +1,135 @@ #include "sea.h" +#include #include +#include -Sea::Sea(WaterSurface& surface) : m_surface{surface} +#include "watersurface.h" + +const double Sea::PHILLIPS_CONSTANT{0.0000001}; +const double Sea::GRAVITATIONAL_CONSTANT{9.8}; + +Sea::Sea(WaterSurfacePtr surface) : + m_surface{surface}, + m_windDirection{1, 0}, + m_windSpeed{10}, + m_randomGenerator{m_randomDevice()}, + m_normalDistribution{0.0, 1.0} +{ + m_fourierAmplitudes.resize(pow(m_surface->size() + 1, 2)); + generateFourierAmplitudes(); + + m_fftwIn = (fftw_complex*) + fftw_malloc(sizeof(fftw_complex) * pow(m_surface->size(), 2)); + m_fftwOut = (fftw_complex*) + fftw_malloc(sizeof(fftw_complex) * pow(m_surface->size(), 2)); + m_fftwPlan = fftw_plan_dft_2d + (m_surface->size(), m_surface->size(), m_fftwIn, m_fftwOut, + FFTW_BACKWARD, FFTW_MEASURE); + + m_startTime = std::chrono::system_clock::now(); +} + +Sea::~Sea() +{ + fftw_destroy_plan(m_fftwPlan); + fftw_free(m_fftwIn); fftw_free(m_fftwOut); +} + +double Sea::getRuntime() const { + auto timeNow = std::chrono::system_clock::now(); + auto durationMs = + std::chrono::duration_cast(timeNow - m_startTime); + + return durationMs.count() / 1000.0; } void Sea::update() { - for (int y = 0; y < m_surface.size(); ++y) { - for (int x = 0; x < m_surface.size(); ++x) { - m_surface.at(x, y) - .setHeight(((double)std::rand()/(double)RAND_MAX)); + using namespace std::complex_literals; + + const double runtime = getRuntime(); + + for (int m = -m_surface->size()/2; m < m_surface->size()/2; ++m) { + const int positiveM = (m + m_surface->size()) % m_surface->size(); + + for (int n = -m_surface->size()/2; n < m_surface->size()/2; ++n) { + const double k = sqrt(pow(spatialFrequencyForIndex(n), 2) + + pow(spatialFrequencyForIndex(m), 2)); + const double omega = sqrt(GRAVITATIONAL_CONSTANT * k); + + std::complex amplitude = + fourierAmplitudeAt(n, m) * exp(1i * omega * runtime) + + std::conj(fourierAmplitudeAt(-n, -m)) * exp(-1i * omega * runtime); + + const int positiveN = (n + m_surface->size()) % m_surface->size(); + int fftwIndex = positiveM + positiveN * m_surface->size(); + + m_fftwIn[fftwIndex][0] = std::real(amplitude); + m_fftwIn[fftwIndex][1] = std::imag(amplitude); } } + + fftw_execute(m_fftwPlan); + + for (int y = 0; y < m_surface->size(); ++y) { + for (int x = 0; x < m_surface->size(); ++x) { + m_surface->at(x, y) + .setHeight(m_fftwOut[y + x * m_surface->size()][0]); + } + } +} + +double Sea::phillipsSpectrum(double k_x, double k_y) const +{ + const double k = sqrt(pow(k_x, 2) + pow(k_y, 2)); + const double L = pow(m_windSpeed, 2) / GRAVITATIONAL_CONSTANT; + + const double cosineFactor = pow((k_x / k) * m_windDirection[0] + + (k_y / k) * m_windDirection[1], 2); + + return PHILLIPS_CONSTANT * exp(-1 / pow(k * L, 2)) / pow(k, 4) * + cosineFactor; +} + +std::complex& Sea::fourierAmplitudeAt(int n, int m) +{ + return m_fourierAmplitudes.at + (n + m_surface->size()/2 + + (m + m_surface->size()/2) * m_surface->size()); +} + +double Sea::spatialFrequencyForIndex(int n) const +{ + return 2 * M_PI * n / m_surface->size(); +} + +void Sea::generateFourierAmplitudes() +{ + for (int m = -m_surface->size()/2; m < m_surface->size()/2; ++m) { + const double k_y = spatialFrequencyForIndex(m); + + for (int n = -m_surface->size()/2; n < m_surface->size()/2; ++n) { + const double k_x = spatialFrequencyForIndex(n); + + std::complex cDist(m_normalDistribution(m_randomGenerator), + m_normalDistribution(m_randomGenerator)); + + fourierAmplitudeAt(n, m) = + cDist * sqrt(phillipsSpectrum(k_x, k_y)) / sqrt(2); + } + } + + for (int n = -m_surface->size()/2; n < m_surface->size()/2; ++n) { + fourierAmplitudeAt(n, m_surface->size()/2) = + fourierAmplitudeAt(n, -m_surface->size()/2); + } + + for (int m = -m_surface->size()/2; m < m_surface->size()/2; ++m) { + fourierAmplitudeAt(m_surface->size()/2, m) = + fourierAmplitudeAt(-m_surface->size()/2, m); + } + + fourierAmplitudeAt(0, 0) = {0, 0}; }