//////////////////////////////////////////////////////////// // Headers //////////////////////////////////////////////////////////// #include "Effect.hpp" #include #include const sf::Font* Effect::s_font = NULL; //////////////////////////////////////////////////////////// // "Pixelate" fragment shader //////////////////////////////////////////////////////////// class Pixelate : public Effect { public: Pixelate() : Effect("Pixelate") { } bool onLoad() { // Load the texture and initialize the sprite if (!m_texture.loadFromFile("resources/background.jpg")) return false; m_sprite.setTexture(m_texture); // Load the shader if (!m_shader.loadFromFile("resources/pixelate.frag", sf::Shader::Fragment)) return false; m_shader.setUniform("texture", sf::Shader::CurrentTexture); return true; } void onUpdate(float, float x, float y) { m_shader.setUniform("pixel_threshold", (x + y) / 30); } void onDraw(sf::RenderTarget& target, sf::RenderStates states) const { states.shader = &m_shader; target.draw(m_sprite, states); } private: sf::Texture m_texture; sf::Sprite m_sprite; sf::Shader m_shader; }; //////////////////////////////////////////////////////////// // "Wave" vertex shader + "blur" fragment shader //////////////////////////////////////////////////////////// class WaveBlur : public Effect { public: WaveBlur() : Effect("Wave + Blur") { } bool onLoad() { // Create the text m_text.setString("Praesent suscipit augue in velit pulvinar hendrerit varius purus aliquam.\n" "Mauris mi odio, bibendum quis fringilla a, laoreet vel orci. Proin vitae vulputate tortor.\n" "Praesent cursus ultrices justo, ut feugiat ante vehicula quis.\n" "Donec fringilla scelerisque mauris et viverra.\n" "Maecenas adipiscing ornare scelerisque. Nullam at libero elit.\n" "Pellentesque habitant morbi tristique senectus et netus et malesuada fames ac turpis egestas.\n" "Nullam leo urna, tincidunt id semper eget, ultricies sed mi.\n" "Morbi mauris massa, commodo id dignissim vel, lobortis et elit.\n" "Fusce vel libero sed neque scelerisque venenatis.\n" "Integer mattis tincidunt quam vitae iaculis.\n" "Vivamus fringilla sem non velit venenatis fermentum.\n" "Vivamus varius tincidunt nisi id vehicula.\n" "Integer ullamcorper, enim vitae euismod rutrum, massa nisl semper ipsum,\n" "vestibulum sodales sem ante in massa.\n" "Vestibulum in augue non felis convallis viverra.\n" "Mauris ultricies dolor sed massa convallis sed aliquet augue fringilla.\n" "Duis erat eros, porta in accumsan in, blandit quis sem.\n" "In hac habitasse platea dictumst. Etiam fringilla est id odio dapibus sit amet semper dui laoreet.\n"); m_text.setFont(getFont()); m_text.setCharacterSize(22); m_text.setPosition(30, 20); // Load the shader if (!m_shader.loadFromFile("resources/wave.vert", "resources/blur.frag")) return false; return true; } void onUpdate(float time, float x, float y) { m_shader.setUniform("wave_phase", time); m_shader.setUniform("wave_amplitude", sf::Vector2f(x * 40, y * 40)); m_shader.setUniform("blur_radius", (x + y) * 0.008f); } void onDraw(sf::RenderTarget& target, sf::RenderStates states) const { states.shader = &m_shader; target.draw(m_text, states); } private: sf::Text m_text; sf::Shader m_shader; }; //////////////////////////////////////////////////////////// // "Storm" vertex shader + "blink" fragment shader //////////////////////////////////////////////////////////// class StormBlink : public Effect { public: StormBlink() : Effect("Storm + Blink") { } bool onLoad() { // Create the points m_points.setPrimitiveType(sf::Points); for (int i = 0; i < 40000; ++i) { float x = static_cast(std::rand() % 800); float y = static_cast(std::rand() % 600); sf::Uint8 r = std::rand() % 255; sf::Uint8 g = std::rand() % 255; sf::Uint8 b = std::rand() % 255; m_points.append(sf::Vertex(sf::Vector2f(x, y), sf::Color(r, g, b))); } // Load the shader if (!m_shader.loadFromFile("resources/storm.vert", "resources/blink.frag")) return false; return true; } void onUpdate(float time, float x, float y) { float radius = 200 + std::cos(time) * 150; m_shader.setUniform("storm_position", sf::Vector2f(x * 800, y * 600)); m_shader.setUniform("storm_inner_radius", radius / 3); m_shader.setUniform("storm_total_radius", radius); m_shader.setUniform("blink_alpha", 0.5f + std::cos(time * 3) * 0.25f); } void onDraw(sf::RenderTarget& target, sf::RenderStates states) const { states.shader = &m_shader; target.draw(m_points, states); } private: sf::VertexArray m_points; sf::Shader m_shader; }; //////////////////////////////////////////////////////////// // "Edge" post-effect fragment shader //////////////////////////////////////////////////////////// class Edge : public Effect { public: Edge() : Effect("Edge Post-effect") { } bool onLoad() { // Create the off-screen surface if (!m_surface.create(800, 600)) return false; m_surface.setSmooth(true); // Load the textures if (!m_backgroundTexture.loadFromFile("resources/sfml.png")) return false; m_backgroundTexture.setSmooth(true); if (!m_entityTexture.loadFromFile("resources/devices.png")) return false; m_entityTexture.setSmooth(true); // Initialize the background sprite m_backgroundSprite.setTexture(m_backgroundTexture); m_backgroundSprite.setPosition(135, 100); // Load the moving entities for (int i = 0; i < 6; ++i) { sf::Sprite entity(m_entityTexture, sf::IntRect(96 * i, 0, 96, 96)); m_entities.push_back(entity); } // Load the shader if (!m_shader.loadFromFile("resources/edge.frag", sf::Shader::Fragment)) return false; m_shader.setUniform("texture", sf::Shader::CurrentTexture); return true; } void onUpdate(float time, float x, float y) { m_shader.setUniform("edge_threshold", 1 - (x + y) / 2); // Update the position of the moving entities for (std::size_t i = 0; i < m_entities.size(); ++i) { sf::Vector2f position; position.x = std::cos(0.25f * (time * i + (m_entities.size() - i))) * 300 + 350; position.y = std::sin(0.25f * (time * (m_entities.size() - i) + i)) * 200 + 250; m_entities[i].setPosition(position); } // Render the updated scene to the off-screen surface m_surface.clear(sf::Color::White); m_surface.draw(m_backgroundSprite); for (std::size_t i = 0; i < m_entities.size(); ++i) m_surface.draw(m_entities[i]); m_surface.display(); } void onDraw(sf::RenderTarget& target, sf::RenderStates states) const { states.shader = &m_shader; target.draw(sf::Sprite(m_surface.getTexture()), states); } private: sf::RenderTexture m_surface; sf::Texture m_backgroundTexture; sf::Texture m_entityTexture; sf::Sprite m_backgroundSprite; std::vector m_entities; sf::Shader m_shader; }; //////////////////////////////////////////////////////////// // "Geometry" geometry shader example //////////////////////////////////////////////////////////// class Geometry : public Effect { public: Geometry() : Effect("Geometry Shader Billboards"), m_pointCloud(sf::Points, 10000) { } bool onLoad() { // Check if geometry shaders are supported if (!sf::Shader::isGeometryAvailable()) return false; // Move the points in the point cloud to random positions for (std::size_t i = 0; i < 10000; i++) { // Spread the coordinates from -480 to +480 // So they'll always fill the viewport at 800x600 m_pointCloud[i].position.x = rand() % 960 - 480.f; m_pointCloud[i].position.y = rand() % 960 - 480.f; } // Load the texture if (!m_logoTexture.loadFromFile("resources/logo.png")) return false; // Load the shader if (!m_shader.loadFromFile("resources/billboard.vert", "resources/billboard.geom", "resources/billboard.frag")) return false; m_shader.setUniform("texture", sf::Shader::CurrentTexture); // Set the render resolution (used for proper scaling) m_shader.setUniform("resolution", sf::Vector2f(800, 600)); return true; } void onUpdate(float time, float x, float y) { // Reset our transformation matrix m_transform = sf::Transform::Identity; // Move to the center of the window m_transform.translate(400, 300); // Rotate everything based on cursor position m_transform.rotate(x * 360.f); // Adjust billboard size to scale between 25 and 75 float size = 25 + std::abs(y) * 50; // Update the shader parameter m_shader.setUniform("size", sf::Vector2f(size, size)); } void onDraw(sf::RenderTarget& target, sf::RenderStates states) const { // Prepare the render state states.shader = &m_shader; states.texture = &m_logoTexture; states.transform = m_transform; // Draw the point cloud target.draw(m_pointCloud, states); } private: sf::Texture m_logoTexture; sf::Transform m_transform; sf::Shader m_shader; sf::VertexArray m_pointCloud; }; //////////////////////////////////////////////////////////// /// Entry point of application /// /// \return Application exit code /// //////////////////////////////////////////////////////////// int main() { // Create the main window sf::RenderWindow window(sf::VideoMode(800, 600), "SFML Shader", sf::Style::Titlebar | sf::Style::Close); window.setVerticalSyncEnabled(true); // Load the application font and pass it to the Effect class sf::Font font; if (!font.loadFromFile("resources/tuffy.ttf")) return EXIT_FAILURE; Effect::setFont(font); // Create the effects std::vector effects; effects.push_back(new Pixelate); effects.push_back(new WaveBlur); effects.push_back(new StormBlink); effects.push_back(new Edge); effects.push_back(new Geometry); std::size_t current = 0; // Initialize them for (std::size_t i = 0; i < effects.size(); ++i) effects[i]->load(); // Create the messages background sf::Texture textBackgroundTexture; if (!textBackgroundTexture.loadFromFile("resources/text-background.png")) return EXIT_FAILURE; sf::Sprite textBackground(textBackgroundTexture); textBackground.setPosition(0, 520); textBackground.setColor(sf::Color(255, 255, 255, 200)); // Create the description text sf::Text description("Current effect: " + effects[current]->getName(), font, 20); description.setPosition(10, 530); description.setFillColor(sf::Color(80, 80, 80)); // Create the instructions text sf::Text instructions("Press left and right arrows to change the current shader", font, 20); instructions.setPosition(280, 555); instructions.setFillColor(sf::Color(80, 80, 80)); // Start the game loop sf::Clock clock; while (window.isOpen()) { // Process events sf::Event event; while (window.pollEvent(event)) { // Close window: exit if (event.type == sf::Event::Closed) window.close(); if (event.type == sf::Event::KeyPressed) { switch (event.key.code) { // Escape key: exit case sf::Keyboard::Escape: window.close(); break; // Left arrow key: previous shader case sf::Keyboard::Left: if (current == 0) current = effects.size() - 1; else current--; description.setString("Current effect: " + effects[current]->getName()); break; // Right arrow key: next shader case sf::Keyboard::Right: if (current == effects.size() - 1) current = 0; else current++; description.setString("Current effect: " + effects[current]->getName()); break; default: break; } } } // Update the current example float x = static_cast(sf::Mouse::getPosition(window).x) / window.getSize().x; float y = static_cast(sf::Mouse::getPosition(window).y) / window.getSize().y; effects[current]->update(clock.getElapsedTime().asSeconds(), x, y); // Clear the window if(effects[current]->getName() == "Edge Post-effect"){ window.clear(sf::Color::White); } else { window.clear(sf::Color(50, 50, 50)); } // Draw the current example window.draw(*effects[current]); // Draw the text window.draw(textBackground); window.draw(instructions); window.draw(description); // Finally, display the rendered frame on screen window.display(); } // delete the effects for (std::size_t i = 0; i < effects.size(); ++i) delete effects[i]; return EXIT_SUCCESS; }