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Andrea Bontempi 2018-02-20 15:21:07 +01:00
parent 43616f7bda
commit a93410a321
7 changed files with 554 additions and 1 deletions
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4
.gitignore vendored Normal file
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*.kdev4
*/.kdev4/*
*/build/*
*/nbproject/*

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CMakeLists.txt Normal file
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cmake_minimum_required(VERSION 2.6)
project(mandelbrot)
set(CMAKE_CXX_FLAGS "${CMAKE_CXX_FLAGS} -std=c++11 -O2 -ffast-math -fopenmp")
set(EXECUTABLE_NAME "mandelbrot")
add_executable(${EXECUTABLE_NAME} main.cpp functions.hpp Fractal.hpp Fractal.cpp)
link_directories(/usr/local/lib)
set(BOOST_LIBS program_options)
find_package(Boost COMPONENTS ${BOOST_LIBS} REQUIRED)
target_link_libraries (${EXECUTABLE_NAME} ${Boost_LIBRARIES})
target_link_libraries (${EXECUTABLE_NAME} sfml-window)
target_link_libraries (${EXECUTABLE_NAME} sfml-system)
target_link_libraries (${EXECUTABLE_NAME} sfml-graphics)
install(TARGETS ${EXECUTABLE_NAME} RUNTIME DESTINATION bin)

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Fractal.cpp Normal file
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#include "Fractal.hpp"
#include <chrono>
#include <cmath>
#include <iostream>
Fractal::Fractal(int image_width, int image_height, Domain domain, std::function<std::complex<double> (std::complex<double>, std::complex<double>)> fractal_function, std::function<sf::Color(int iteration_number, int max_iterations)> render_function) : domain(domain) {
this->fractal_function = fractal_function;
this->render_function = render_function;
this->image_height = image_height;
this->image_width = image_width;
this->frame.create(image_width, image_height, sf::Color(0, 0, 0));
this->hasChanged = true;
}
void Fractal::setFractalFunction(std::function<std::complex<double> (std::complex<double>, std::complex<double>)> fractal_function) {
this->fractal_function = fractal_function;
this->hasChanged = true;
}
void Fractal::setRenderFunction(std::function<sf::Color (int iteration_number, int max_iterations)> render_function) {
this->render_function = render_function;
this->hasChanged = true;
}
int Fractal::compute_point(std::complex<double> point, int max_iterations) {
std::complex<double> z(0);
int iter = 0;
while (abs(z) < 2.0 && iter < max_iterations) {
z = this->fractal_function(z, point);
iter++;
}
return iter;
}
std::complex<double> Fractal::scale_point(std::complex<double> point) {
std::complex<double> aux(point.real() / (double)this->image_width * this->domain.width() + this->domain.x_min, point.imag() / (double)this->image_height * this->domain.height() + domain.y_min);
return aux;
}
sf::Image Fractal::getFrame(){
if (this->hasChanged) {
std::chrono::steady_clock::time_point start = std::chrono::steady_clock::now();
int max_iterations = compute_max_iterations(this->image_width, this->domain.width());
#pragma omp parallel for
for(int y = 0; y < this->image_height; y++) {
for(int x = 0; x < this->image_width; x++) {
std::complex<double> point(x, y);
point = scale_point(point);
int iterations = compute_point(point, max_iterations);
sf::Color color = this->render_function(iterations, max_iterations);
this->frame.setPixel(x, y, color);
}
}
std::chrono::steady_clock::time_point end = std::chrono::steady_clock::now();
auto t = std::chrono::duration_cast<std::chrono::milliseconds>(end - start).count();
std::cerr << "Frame> Time: " << t << "ms, Max iterations: " << max_iterations << std::endl;
this->hasChanged = false;
}
return this->frame;
}
void Fractal::moveTo(int x, int y) {
std::complex<double> point(x, y);
point = this->scale_point(point);
this->domain.centralize(point);
this->hasChanged = true;
}
void Fractal::moveBy(double x, double y) {
this->domain.move(x, y);
this->hasChanged = true;
}
void Fractal::zoom(double factor, bool invert) {
this->domain.zoom((invert)?1/factor:factor);
this->hasChanged = true;
}
int Fractal::compute_max_iterations(int window_width, double domain_width) {
int max = 50 * std::pow(std::log10(window_width / domain_width), 1.25);
return (max > 0)? max : 0;
}

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Fractal.hpp Normal file
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#ifndef LIBFRACTAL_H
#define LIBFRACTAL_H
#include <functional>
#include <complex>
#include <SFML/Graphics.hpp>
#include "functions.hpp"
struct Domain {
double x_min, x_max, y_min, y_max;
Domain(double x_min, double x_max, double y_min, double y_max) : x_min(x_min), x_max(x_max), y_min(y_min), y_max(y_max) {}
double width() {
return x_max - x_min;
}
double height() {
return y_max - y_min;
}
double size() {
return width() * height();
}
double ratio() {
return width() / height();
}
void setRatio(double ratio) {
double factor = (width() / ratio) / 2;
double w = (y_max + y_min) / 2;
y_min = w - factor;
y_max = w + factor;
}
void zoom(double factor) {
double x_frac = width() / 2;
double y_frac = height() / 2;
double x_factor = x_frac - (x_frac * factor);
double y_factor = y_frac - (y_frac * factor);
x_min -= x_factor;
y_min -= y_factor;
x_max += x_factor;
y_max += y_factor;
}
void move(double x, double y) {
double deltax = x * (x_max - x_min);
x_min += deltax;
x_max += deltax;
double deltay = y * (y_max - y_min);
y_min += deltay;
y_max += deltay;
}
void centralize(std::complex<double> point) {
double x_frac = width() / 2;
double y_frac = height() / 2;
x_min = point.real() - x_frac;
y_min = point.imag() - y_frac;
x_max = point.real() + x_frac;
y_max = point.imag() + y_frac;
}
};
class Fractal {
private:
int image_width, image_height;
std::function<std::complex<double>(std::complex<double>, std::complex<double>)> fractal_function;
std::function<sf::Color(int iteration_number, int max_iterations)> render_function;
sf::Image frame;
bool hasChanged;
Domain domain;
std::complex<double> scale_point(std::complex<double> point);
int compute_point(std::complex<double> point, int max_iterations);
int compute_max_iterations(int window_width, double domain_width);
public:
Fractal(int image_width,
int image_height,
Domain domain,
std::function<std::complex<double>(std::complex<double>, std::complex<double>)> fractal_function = fractal_mandelbrot,
std::function<sf::Color(int iteration_number, int max_iterations)> render_function = render_smooth
);
void setFractalFunction(std::function<std::complex<double>(std::complex<double>, std::complex<double>)> fractal_function);
void setRenderFunction(std::function<sf::Color(int iteration_number, int max_iterations)> render_function);
void moveTo(int x, int y);
void moveBy(double x, double y);
void zoom(double factor, bool invert = false);
sf::Image getFrame();
Domain& getDomain() {
return this->domain;
}
};
#endif //LIBFRACTAL_H

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README.md
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# OpenMandelbrot # OpenMandelbrot
Open Mandelbrot
Build and install
=================
Installing the dependencies
---------------------------
- cmake
- libboost
- SFML
Compile!
--------
```sh
git clone https://github.com/Andreabont/OpenMandelbrot.git
mkdir build
cd build
cmake ..
make
make install

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#ifndef LIBFUNCTIONS_H
#define LIBFUNCTIONS_H
#include <complex>
#include <SFML/Graphics.hpp>
inline std::complex<double> fractal_mandelbrot(std::complex<double> z, std::complex<double> c) {
return (z * z) + c;
}
inline std::complex<double> fractal_triple_mandelbrot(std::complex<double> z, std::complex<double> c) {
return (z * z * z) + c;
}
inline std::complex<double> fractal_quadruple_mandelbrot(std::complex<double> z, std::complex<double> c) {
return (z * z * z * z) + c;
}
inline std::complex<double> fractal_quintuple_mandelbrot(std::complex<double> z, std::complex<double> c) {
return (z * z * z * z * z) + c;
}
inline sf::Color render_linear(int iteration_number, int max_iterations) {
int N = 256; // colors per element
int N3 = N * N * N;
double t = (double)iteration_number/(double)max_iterations;
// expand n on the 0 .. 256^3 interval (integers)
iteration_number = (int)(t * (double) N3);
int b = iteration_number/(N * N);
int nn = iteration_number - b * N * N;
int r = nn/N;
int g = nn - r * N;
return sf::Color(r, g, b);
}
inline sf::Color render_smooth(int iteration_number, int max_iterations) {
double t = (double)iteration_number/(double)max_iterations;
// Use smooth polynomials for r, g, b
int r = (int)(9*(1-t)*t*t*t*255);
int g = (int)(15*(1-t)*(1-t)*t*t*255);
int b = (int)(8.5*(1-t)*(1-t)*(1-t)*t*255);
return sf::Color(r, g, b);
}
inline sf::Color render_black_and_white(int iteration_number, int max_iterations) {
double t = (double)iteration_number/(double)max_iterations;
return (t != 1)? sf::Color(0, 0, 0) : sf::Color(255, 255, 255);
}
inline sf::Color render_green_gradient(int iteration_number, int max_iterations) {
double t = (double)iteration_number/(double)max_iterations;
if(t == 1) return sf::Color(0, 0, 0);
return (t > 0.5)? sf::Color(t*255, 255, t*255) : sf::Color(0, t*255, 0);
}
#endif //LIBFUNCTIONS_H

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#include <iostream>
#include <tuple>
#include <string>
#include <SFML/Graphics.hpp>
#include <boost/program_options.hpp>
#include <iomanip>
#include <ctime>
#include <chrono>
#include "functions.hpp"
#include "Fractal.hpp"
const double DOMAIN_X_MIN = -2.0;
const double DOMAIN_X_MAX = 2.0;
const double DOMAIN_Y_MIN = -1.7;
const double DOMAIN_Y_MAX = 1.7;
const int IMAGE_WIDTH = 1920;
const int IMAGE_HEIGHT = 1080;
const int FRAMERATE = 20;
int main(int argc, char **argv) {
boost::program_options::options_description po ("Mandelbrot");
po.add_options()
("help", "Help")
("noratio", "Don't force the window ratio on domain")
("framerate", boost::program_options::value<int>()->default_value(FRAMERATE), "Framerate")
("width", boost::program_options::value<int>()->default_value(IMAGE_WIDTH), "Window width")
("height", boost::program_options::value<int>()->default_value(IMAGE_HEIGHT), "Window height")
("domXmin", boost::program_options::value<double>()->default_value(DOMAIN_X_MIN), "Domain X (Min)")
("domXmax", boost::program_options::value<double>()->default_value(DOMAIN_X_MAX), "Domain X (Max)")
("domYmin", boost::program_options::value<double>()->default_value(DOMAIN_Y_MIN), "Domain Y (Min)")
("domYmax", boost::program_options::value<double>()->default_value(DOMAIN_Y_MAX), "Domain Y (Max)")
("filename", boost::program_options::value<std::string>(), "Filename")
;
boost::program_options::variables_map vm;
boost::program_options::store(boost::program_options::parse_command_line(argc, argv, po), vm);
boost::program_options::notify(vm);
if (vm.count("help")) {
std::cout << po << std::endl;
return 0;
}
int screen_width = vm["width"].as<int>();
int screen_height = vm["height"].as<int>();
double windowRatio = (double)screen_width / (double)screen_height;
Fractal mandelbrot(
screen_width,
screen_height,
Domain(
vm["domXmin"].as<double>(),
vm["domXmax"].as<double>(),
vm["domYmin"].as<double>(),
vm["domYmax"].as<double>()
)
);
if(!vm.count("noratio")){
std::cerr << "Force ratio " << windowRatio << std::endl;
mandelbrot.getDomain().setRatio(windowRatio);
}
if(vm.count("filename")) {
mandelbrot.getFrame().saveToFile(vm["filename"].as<std::string>());
std::cerr << "Screenshot stored in file " << vm["filename"].as<std::string>() << std::endl;
return 0;
}
sf::RenderWindow window(sf::VideoMode(screen_width, screen_height), "Mandelbrot");
window.setFramerateLimit(vm["framerate"].as<int>());
sf::Texture texture;
sf::Sprite sprite;
while (window.isOpen()) {
sf::Event event;
while (window.pollEvent(event)) {
switch (event.type) {
case sf::Event::Closed:
window.close();
break;
case sf::Event::MouseButtonReleased: {
sf::Vector2i mousePosition = sf::Mouse::getPosition(window);
switch (event.mouseButton.button) {
case sf::Mouse::Left:
mandelbrot.moveTo(mousePosition.x, mousePosition.y);
break;
case sf::Mouse::Right:
mandelbrot.moveTo(mousePosition.x, mousePosition.y);
break;
default:
break;
}
}
break;
case sf::Event::MouseWheelMoved:
if(event.mouseWheel.delta > 0) {
mandelbrot.zoom(1.05);
} else {
mandelbrot.zoom(1.05, true);
}
break;
case sf::Event::KeyPressed:
switch (event.key.code) {
case sf::Keyboard::Escape:
window.close();
break;
case sf::Keyboard::Key::Add:
mandelbrot.zoom(1.5);
break;
case sf::Keyboard::Key::Subtract:
mandelbrot.zoom(1.5, true);
break;
case sf::Keyboard::Key::Right:
mandelbrot.moveBy(0.01, 0);
break;
case sf::Keyboard::Key::Left:
mandelbrot.moveBy(-0.01, 0);
break;
case sf::Keyboard::Key::Up:
mandelbrot.moveBy(0, -0.01);
break;
case sf::Keyboard::Key::Down:
mandelbrot.moveBy(0, 0.01);
break;
case sf::Keyboard::Key::S: {
std::time_t t = std::time(nullptr);
std::tm tm = *std::localtime(&t);
std::stringstream filename;
filename << "Screenshot_" << std::put_time(&tm, "%Y%m%d%H%M%S") << ".jpeg";
mandelbrot.getFrame().saveToFile(filename.str());
std::cerr << "Screenshot stored in file " << filename.str() << std::endl;
}
break;
case sf::Keyboard::Key::D: {
std::cerr << std::scientific << std::setprecision(10) << "domXmin=" << mandelbrot.getDomain().x_min << ", domXmax=" << mandelbrot.getDomain().x_max << ", domYmin=" << mandelbrot.getDomain().y_min << ", domYmax=" << mandelbrot.getDomain().y_max << std::endl;
}
break;
// Renderer selection
case sf::Keyboard::Key::Q:
std::cerr << "Selected smooth renderer" << std::endl;
mandelbrot.setRenderFunction(render_smooth);
break;
case sf::Keyboard::Key::W:
std::cerr << "Selected linear renderer" << std::endl;
mandelbrot.setRenderFunction(render_linear);
break;
case sf::Keyboard::Key::E:
std::cerr << "Selected black&white renderer" << std::endl;
mandelbrot.setRenderFunction(render_black_and_white);
break;
case sf::Keyboard::Key::R:
std::cerr << "Selected green gradient renderer" << std::endl;
mandelbrot.setRenderFunction(render_green_gradient);
break;
// Fractal selection
case sf::Keyboard::Key::Num1:
std::cerr << "Selected mandelbrot algorithm" << std::endl;
mandelbrot.setFractalFunction(fractal_mandelbrot);
break;
case sf::Keyboard::Key::Num2:
std::cerr << "Selected triple mandelbrot algorithm" << std::endl;
mandelbrot.setFractalFunction(fractal_triple_mandelbrot);
break;
case sf::Keyboard::Key::Num3:
std::cerr << "Selected quadruple mandelbrot algorithm" << std::endl;
mandelbrot.setFractalFunction(fractal_quadruple_mandelbrot);
break;
case sf::Keyboard::Key::Num4:
std::cerr << "Selected quintuple mandelbrot algorithm" << std::endl;
mandelbrot.setFractalFunction(fractal_quintuple_mandelbrot);
break;
default:
break;
}
default:
break;
}
}
window.clear(sf::Color::Black);
texture.loadFromImage(mandelbrot.getFrame());
sprite.setTexture(texture);
window.draw(sprite);
window.display();
}
return 0;
}