KlassischeKeplerKriege/game/renderer_polygon_3d/renderer_polygon_3d.cpp

#include "renderer_polygon_3d.hpp"

#include <iostream>

#include "state/events/explosion_event.hpp"
#include "state/events/missile_event.hpp"
#include "state/events/ship_event.hpp"

#include "developer_console.hpp"

namespace endofthejedi {
void RendererPolygon3d::setup() {
    m_lastTime = -1.0;

    // std::cout << "setup polygon 3d" << std::endl;

    m_shader_game_objects.init();
    m_shader_game_objects.loadFile("../data/shader/gameobjects.vert",
                                   GL_VERTEX_SHADER);
    m_shader_game_objects.loadFile("../data/shader/gameobjects.frag",
                                   GL_FRAGMENT_SHADER);

    m_shader_particles.init();
    m_shader_particles.loadFile("../data/shader/particle.vert",
                                GL_VERTEX_SHADER);
    m_shader_particles.loadFile("../data/shader/particle.frag",
                                GL_FRAGMENT_SHADER);

    m_shader_background.init();
    m_shader_background.loadFile("../data/shader/background.vert",
                                 GL_VERTEX_SHADER);
    m_shader_background.loadFile("../data/shader/background.frag",
                                 GL_FRAGMENT_SHADER);

    // addModel("../data/mesh/small_atomic_bomb.stl", &m_missileModel);
    addModel("../data/mesh/rocket.stl", &m_missileModel);
    addModel("../data/mesh/planet_128.stl", &m_planetModel);
    addModel("../data/mesh/ship_ufo.stl", &m_shipModel);

    m_texture = nullptr;
    //m_backgroundTexturePath = "../data/img/background_3.png";
    m_backgroundTexturePath = "../data/img/stars_nebular.png";
    loadBackgroundTexture();

    m_postprocess_shader.init();
    m_postprocess_shader.loadFile("../data/shader/postprocess.vert",
                                  GL_VERTEX_SHADER);
    m_postprocess_shader.loadFile("../data/shader/postprocess.frag",
                                  GL_FRAGMENT_SHADER);

    m_multitexture_shader.init();
    m_multitexture_shader.loadFile("../data/shader/multitexture.vert",
                                   GL_VERTEX_SHADER);
    m_multitexture_shader.loadFile("../data/shader/multitexture.frag",
                                   GL_FRAGMENT_SHADER);
    m_postprocess_fbo.init();
    m_postprocess_tex0.init();
    m_postprocess_tex1.init();

    developer::DeveloperConsole::instance().addCallback(
        "reload_bg", [=](const std::string &) {
            loadBackgroundTexture();
            return developer::resultOkay();
        });

    developer::DeveloperConsole::instance().addCallback(
        "set_bg", [=](const std::string &str) {
            std::string token;
            std::string rest;
            util::splitIntoTokenAndRest(str, token, rest);

            m_backgroundTexturePath = token;
            loadBackgroundTexture();
            return developer::resultOkay();
        });
}

void RendererPolygon3d::loadBackgroundTexture() {
    // m_texture = new ImageTexture("../data/img/test.png");
    if (m_texture != nullptr) {
        delete (m_texture);
    }

    //"../data/img/stars_nebular.png");
    m_texture = new ImageTexture(m_backgroundTexturePath);

    glActiveTexture(GL_TEXTURE0);
    m_texture->loadPng();

    //std::cout << "texture loading: " << m_texture->valid() << std::endl;
    if (!m_texture->valid()) {
        std::cout << "loading failed!";
        return;
        // exit(-1);
    }

    //glm::vec2 s = m_texture->size();
    //std::cout << "texture size is " << s.x << " X " << s.y << std::endl;
}

void RendererPolygon3d::renderBackgroundImage() {
    m_shader_background.bind();

    glUniform2fv(m_shader_background.location("uvScale"), 1,
                 glm::value_ptr(m_texture->uvScale()));

    glActiveTexture(GL_TEXTURE0);
    glEnable(GL_TEXTURE_2D);
    glBindTexture(GL_TEXTURE_2D, m_texture->textureId());

    // drawNdcQuad();
    glColor3f(1.0, 0.0, 0.0);
    glBegin(GL_QUADS);
    glVertex2f(-1.0f, -1.0f);
    glVertex2f(1.0f, -1.0f);
    glVertex2f(1.0f, 1.0f);
    glVertex2f(-1.0f, 1.0f);
    glEnd();
}

void RendererPolygon3d::render(const game::State *state) {
    if (m_lastTime == -1.0) {
        m_lastTime = state->timestamp();
    }

    float dt = state->timestamp() - m_lastTime;
    if (dt < 0.0) {
        dt = 0.0;
    }

    m_state = state;
    advanceGraphicObjects(dt);

    // TODO: add stars (texture)
    // TODO: add dust particles
    // TODO: add little rocks flying around

    glClearColor(0.0, 0.0, 0.0, 1.0);
    // glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT);

    m_postprocess_fbo.bind();

    m_postprocess_tex0.bind();
    m_postprocess_tex0.fill(0, 3, m_w, m_h, 0, GL_RGB, GL_FLOAT, NULL);
    glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_NEAREST);
    glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST);

    m_postprocess_tex1.bind();
    m_postprocess_tex1.fill(0, 3, m_w, m_h, 0, GL_RGB, GL_FLOAT, NULL);
    glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_NEAREST);
    glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_NEAREST);

    m_postprocess_fbo.attachTexture(GL_COLOR_ATTACHMENT0,
                                    m_postprocess_tex0.getName());
    renderBackgroundImage();

    m_shader_game_objects.bind();

    configureLightningInShader(&m_shader_game_objects);

    renderPlanets();
    renderShips();
    renderMissiles();

    renderParticles();

    renderTraces();

    glUniform1f(m_shader_game_objects.location("aspectRatio"), m_aspectRatio);
    m_postprocess_tex1.bind();
    m_postprocess_fbo.attachTexture(GL_COLOR_ATTACHMENT0,
                                    m_postprocess_tex1.getName());
    // glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT);

    m_shader_game_objects.bind();
    configureLightningInShader(&m_shader_game_objects);
    glUniform1f(m_shader_game_objects.location("aspectRatio"), m_aspectRatio);
    renderPlanets();
    renderShips();
    renderMissiles();

    renderParticles();

    renderTraces();

    // postprocessing
    m_postprocess_shader.bind();
    glActiveTexture(GL_TEXTURE0);
    m_postprocess_tex1.bind();

    glUniform1i(m_postprocess_shader.location("tex"), 0);
    glUniform2f(m_postprocess_shader.location("uvScale"), 1, 1);

    for (int i = 0; i < 2; i++) {
        glUniform2f(m_postprocess_shader.location("scale"), 2.0f / m_w, 0.0f);

        glBegin(GL_QUADS);
        glVertex2f(-1.0f, -1.0f);
        glVertex2f(1.0f, -1.0f);
        glVertex2f(1.0f, 1.0f);
        glVertex2f(-1.0f, 1.0f);
        glEnd();

        glUniform2f(m_postprocess_shader.location("scale"), 0.0f, 2.0f / m_h);

        glBegin(GL_QUADS);
        glVertex2f(-1.0f, -1.0f);
        glVertex2f(1.0f, -1.0f);
        glVertex2f(1.0f, 1.0f);
        glVertex2f(-1.0f, 1.0f);
        glEnd();
    }

    m_postprocess_fbo.unbind();

    // multitexturing (final step)
    m_multitexture_shader.bind();

    glUniform1i(m_multitexture_shader.location("tex0"), 0);
    glUniform1i(m_multitexture_shader.location("tex1"), 1);
    glUniform2f(m_multitexture_shader.location("uvScale"), 1, 1);
    glUniform2f(m_multitexture_shader.location("scale"), 0.2f / 1000.0f, 0.0f);

    glActiveTexture(GL_TEXTURE0);
    m_postprocess_tex0.bind();
    glActiveTexture(GL_TEXTURE1);
    m_postprocess_tex1.bind();
    
    glColor3f(1.0, 0.0, 0.0);
    glBegin(GL_QUADS);
    glVertex2f(-1.0f, -1.0f);
    glVertex2f(1.0f, -1.0f);
    glVertex2f(1.0f, 1.0f);
    glVertex2f(-1.0f, 1.0f);
    glEnd();

    m_lastTime = state->timestamp();
}

void RendererPolygon3d::renderParticles() {
    m_shader_particles.bind();

    glUniform1f(m_shader_particles.location("aspectRatio"), m_aspectRatio);

    for (ParticleBatch *batch : m_particles) {
        batch->bind();
        batch->render(&m_shader_particles);
    }
}

void RendererPolygon3d::addExplosionEffect(size_t id,
                                           const glm::vec2 &explCenter,
                                           const glm::vec2 &missileVelocity,
                                           bool isPlanetHit, size_t n,
                                           float duration) {

	(void) missileVelocity;

    // float particleRadius = 0.005;
    // float particleRadius = 0.003;
    float particleRadius = 0.02;

    // TODO: use this as shader input too and make the area 2x around this
    // so that it stays hot/yellow for 2/3 of the time
    float explCoreSize = 0.02f;
    float maxVelocity = 0.4f;

    ParticleBatch *batch = new ParticleBatch(id, n, particleRadius, duration);
    batch->setup(&m_shader_particles);
    batch->setCenter(glm::vec3(explCenter, 0.0));
    batch->setMaxVelocity(maxVelocity);

    for (size_t i = 0; i < n; i++) {
        // distribute in a circle
        // float t = 2.0 * M_PI * i / (float) n;
        // t += 0.2*util::randf_m1_1();

        // with random velocities
        // this is 3d because it looks better if some particles leave/enter
        // the space and they are not all on one plane.
        // especially in 3d this would look bad without 3d velocity vector.
        // glm::vec3 v = 0.5f*glm::vec3(sin(t), cos(t), util::randf_m1_1());

        glm::vec3 pos =
            glm::vec3(explCenter, 0.0) + glm::ballRand(explCoreSize);

        glm::vec3 v = glm::ballRand(maxVelocity);

        // TODO: is that good?
        if (isPlanetHit) {
            v *= util::randf_0_1() * util::randf_0_1() * util::randf_0_1();
        } else {
            v *= util::randf_0_1();
        }

        // find collisions with planetns and limit max distance so particles
        // won't fly through planets
        // float maxDist = 0.1;
        // float maxDist = 0.1*util::randf_0_1();
        bool isInsidePlanet = false;
        float maxParticleDist = INFINITY;

        const game::Planet *nearestPlanet = nullptr;
        for (const game::Planet *planet : m_state->planets) {
            const glm::vec3 ppos3 = glm::vec3(planet->position, 0.0f);

            // TODO: that's slightly wrong. use intersection for this.
            float dist = glm::distance(ppos3, pos);
            if (dist <= planet->radius) {
                isInsidePlanet = true;
                nearestPlanet = planet;
            }
            if (isInsidePlanet) {
                // skip searching for nearer planets once we are inside some
                // planet as the position/velocity will be changed to start
                // at the surface of the planet we were in with
                // reflected or planet-normal velocity.
                continue;
            }
            // TODO: if inside, move position so that it looks like
            // reflecting the particle from the planet
            bool fliesInPlanetDirection = glm::dot(v, ppos3 - pos) > 0.0f;
            if (dist < maxParticleDist && fliesInPlanetDirection) {
                nearestPlanet = planet;
                maxParticleDist = dist;
            }
        }

        bool makeStationary = false;

        if (isInsidePlanet && isPlanetHit) {
            util::IntersectionTest intersect;
            if (!intersect.raySphere(glm::vec3(explCenter, 0.0f), v,
                                     glm::vec3(nearestPlanet->position, 0.0f),
                                     nearestPlanet->radius)) {
                makeStationary = true;
                // std::cout<<"warning: intersection should be valid!" <<
                // std::endl;
                // TODO: must be as they lie on a plane and the dist is < as
                // the radius.
                // handle if this is wrong.

            } else {
                // simple reflection, ignoring the missile velocity: this looks
                // good enough
                glm::vec3 planetNormal = glm::normalize(
                    pos - glm::vec3(nearestPlanet->position, 0.0f));
                v = glm::length(v) * planetNormal;

                // TODO
                // considering the missile velocity is not yet working:

                // set position to the intersection point between explosion
                // center and planet surface
                // pos = intersect.pointAtDistance(intersect.distance());
                // v = glm::vec3(missileVelocity, 0.0f);
                // v = v - 2.0f*glm::dot(v, planetNormal) * planetNormal;
                // v *= 4.0;
                // maxParticleDist = 100.0;
                // v = -v;

                // pos = glm::vec3(nearestPlanet->position, 0.0f) +
                // nearestPlanet->radius*planetNormal;

                // set position to the intersection point between explosion
                // center and planet surface
                // const glm::vec3 planetNormal =
                // glm::vec3(glm::normalize(explCenter -
                // nearestPlanet->position), 0.0f);

                // pos = glm::vec3(nearestPlanet->position, 0.0f) +
                // nearestPlanet->radius*planetNormal;

                // build new velocity by reflecting the old velocity on the
                // planet normal
                // TODO: add a bit random
                // TODO: add reflection
                // TODO: distribute particles around main reflection angle and
                // TODO: add material exhaust that is specific for the planet.
                // TODO: spawn waves on water planet
                // TODO: start fire on gas planet
                // v = glm::length(v) * planetNormal;
                // v = v - 2.0f*glm::dot(v, planetNormal) * planetNormal;
                // v = glm::length(v) * planetNormal;

                // glm::vec3 r  = v - 2.0f*glm::dot(v, planetNormal) *
                // planetNormal;
                // glm::vec3 vn = glm::length(v) * planetNormal;
                // v = (r+vn) / 2.0f;

                // glm::vec3 vc = glm::vec3(nearestPlanet->position-explCenter,
                // 0.0f);
                // glm::vec3 r  = vc - 2.0f*glm::dot(vc, planetNormal) *
                // planetNormal;
                // v = r;
            }
        } else if (isInsidePlanet && !isPlanetHit) {
            // if a planet is just hit by explosions particles but not the
            // missile itself, don't reflect the particles in the planet.
            // just set them as stationary at place of explosion
            makeStationary = true;
        }

        if (makeStationary) {
            v = glm::vec3(0.0f, 0.0f, 0.0f);
            pos = glm::vec3(explCenter, 0.0f);
            ;
        }

        batch->setParticle(i, pos, v, maxParticleDist);
    }

    batch->upload();

    m_particles.push_back(batch);
}

void RendererPolygon3d::advanceGraphicObjects(float dt) {
#if 0
        for (const game::Explosion *expl : m_state->explosions) {
            bool gotIt = false;
            for (ParticleBatch *batch : m_particles) {
                if (batch->id() == expl->id) {
                    gotIt = true;
                    break;
                }
            }

            if (!gotIt) {
                addExplosionEffect(
                        expl->id, expl->position,
                        glm::vec3(expl->missileVelocity,1.0),
                        (expl->hit == game::Hit::Planet),
                        1000, 1.0);
            }
        }
#endif

    for (auto *evt : m_state->currentStateUpdateEvents()) {
        auto type = evt->eventType();
        auto cycle = evt->lifeCycle();

        if (type == game::EventType::Explosion) {
            if (cycle == game::LifeCycle::Create) {
                game::ExplosionEvent *ee =
                    static_cast<game::ExplosionEvent *>(evt);
                game::Explosion *expl =
                    static_cast<game::Explosion *>(ee->object());

                addExplosionEffect(expl->id, expl->position,
                                   glm::vec3(expl->missileVelocity, 1.0),
                                   (expl->hit == game::Hit::Planet), 1000, 1.0);
            }
        } else if (type == game::EventType::Ship) {
            game::ShipEvent *me = static_cast<game::ShipEvent *>(evt);
            game::Ship *ship = static_cast<game::Ship *>(me->object());

            // is always modificated
            if (cycle == game::LifeCycle::Create) {
                // std::cout<<"[renderer] adding missile #" << missile->id <<
                // std::endl;
                m_ships.push_back(ship);

            } else if (cycle == game::LifeCycle::Destroy) {
                // std::cout<<"[renderer] removing missile #" << missile->id <<
                // std::endl;
                m_ships.remove(ship);
            }
        } else if (type == game::EventType::Missile) {
            game::MissileEvent *me = static_cast<game::MissileEvent *>(evt);
            game::Missile *missile = static_cast<game::Missile *>(me->object());

            // is always modificated
            if (cycle == game::LifeCycle::Create) {
                // std::cout<<"[renderer] adding missile #" << missile->id <<
                // std::endl;
                m_missiles.push_back(missile);

            } else if (cycle == game::LifeCycle::Destroy) {
                // std::cout<<"[renderer] removing missile #" << missile->id <<
                // std::endl;
                m_missiles.remove(missile);
            }
        }
    }

    // if (m_particles.size() == 0) {
    //    addExplosionEffect(0, glm::vec2(0.0, 0.0), glm::vec2(0.0, 0.0), false,
    //    10000, 2.0);
    //}

    std::vector<ParticleBatch *> rm;

    for (ParticleBatch *batch : m_particles) {
        batch->tick(dt);
        if (batch->done()) {
            rm.push_back(batch);
        }
    }

    for (ParticleBatch *batch : rm) {
        m_particles.remove(batch);
        delete (batch);
    }
}

void RendererPolygon3d::renderPlanets() {
    m_planetModel->bind();

    // TODO: put material into attributes and render witd glDrawInstanced
    // too (same for missiles)
    for (const game::Planet *planet : m_state->planets) {
        glm::mat4 model = computeModelMatrix(planet);
        glUniformMatrix4fv(m_shader_game_objects.location("model"), 1, GL_FALSE,
                           glm::value_ptr(model));

        glm::vec3 c = planet->getColor();
        glUniform3f(m_shader_game_objects.location("materialColor"), c.x, c.y,
                    c.z);
        glUniform1i(m_shader_game_objects.location("materialSeed"),
                    planet->seed);
        glUniform1i(m_shader_game_objects.location("materialKind"),
                    (int)planet->material);

        m_planetModel->render();
    }
}

void RendererPolygon3d::renderMissiles() {
    // TODO: add fire trail for missiles near the sun

    m_missileModel->bind();

    for (const game::Missile *missile : m_missiles) {
        glm::vec3 c = glm::vec3(1.0, 1.0, 0.3);
        glUniform3f(m_shader_game_objects.location("materialColor"), c.x, c.y,
                    c.z);

        // TODO: rename functions so their name represents what args they
        // take
        glm::mat4 model = computeModelMatrix(missile);
        glUniformMatrix4fv(m_shader_game_objects.location("model"), 1, GL_FALSE,
                           glm::value_ptr(model));

        m_missileModel->render();
    }
}

void RendererPolygon3d::renderShips() {
    m_shipModel->bind();

    for (const game::Ship *ship : m_ships) {
        glm::mat4 model = computeModelMatrix(ship);
        glUniformMatrix4fv(m_shader_game_objects.location("model"), 1, GL_FALSE,
                           glm::value_ptr(model));

        glm::vec3 c = glm::vec3(0.1, 1.0, 0.2);
        glUniform3f(m_shader_game_objects.location("materialColor"), c.x, c.y,
                    c.z);

        m_shipModel->render();
    }
}

void RendererPolygon3d::addModel(const std::string &filename,
                                 PolygonModel **dest) {

    // std::cout<<"adding a model: " << filename << std::endl;
    *dest = new PolygonModel(filename);
    if (!(*dest)->import()) {
        std::cout << "error: failed to load needed model!!!" << std::endl
                  << std::endl;
        exit(-1);
    }

    (*dest)->setup(&m_shader_game_objects);
    (*dest)->uploadToOpenGl();

    m_models.push_back(*dest);
}

glm::mat4 RendererPolygon3d::computeModelMatrix(const game::Planet *planet) {
    return computeModelMatrix(planet->position, planet->radius);
}

glm::mat4 RendererPolygon3d::computeModelMatrix(const game::Missile *missile) {
    glm::vec2 vn = glm::normalize(missile->velocity);
    float a = std::atan2(vn.y, vn.x);

    glm::mat4 mat = computeModelMatrix(missile->position, 0.1f, a);

    // TODO: which visual size has the rocket? in game its just a point with
    // no size because all others have size.
    // for atomic bomb
    // return computeModelMatrix(missile->position, 0.03f, a);

    // flipped too
    mat = glm::rotate(mat, (float)M_PI / 2.0f, glm::vec3(0.0f, 1.0f, 0.0f));

    return mat;
}

glm::mat4 RendererPolygon3d::computeModelMatrix(const game::Ship *ship) {
    // TODO: rotate them before shooting, that looks better
    glm::mat4 mat = computeModelMatrix(ship->position, m_state->shipRadius());

    // XXX model is flipped
    // glm::mat4 mat = computeModelMatrix(ship->position, 0.3);
    mat = glm::rotate(mat, (float)M_PI, glm::vec3(0.0f, 1.0f, 0.0f));
    return mat;
}

glm::mat4 RendererPolygon3d::computeModelMatrix(const glm::vec2 &pos,
                                                float scale, float angle) {
    // init as identity matrix
    glm::mat4 model;

    model = glm::translate(model, glm::vec3(pos, 0.0));

    if (scale != 1.0) {
        model = glm::scale(model, glm::vec3(scale));
    }

    if (angle != 0.0) {
        model = glm::rotate(model, angle, glm::vec3(0.0f, 0.0f, 1.0f));
    }

    return model;
}

void RendererPolygon3d::renderTraces() {
    // revert to default
    glUseProgram(0);

    // TODO dont use line mode. make that with own quads
    glPolygonMode(GL_FRONT, GL_LINE);
    glLineWidth(2.0f);
    for (const game::Trace *trace : m_state->traces) {
        float fade_out = 1.0;
        if (trace->missile == nullptr) {
            fade_out = 1.0 - (trace->age / trace->maxAge);
        }

        glColor3f(0.0, 0.5 * fade_out, 0.5 * fade_out);
        glBegin(GL_LINE_STRIP);
        for (const game::Trace::TracePoint &tp : trace->points) {
            glVertex2f(tp.position.x, tp.position.y);
        }
        glEnd();
    }
    glLineWidth(1.0f);
    glPolygonMode(GL_FRONT, GL_FILL);
}

void RendererPolygon3d::configureLightningInShader(Shader *shader) const {
    // TODO: add a few small lights for explosions so they lit the
    // surroundsings

    // TODO: use the sun planet color for this!
    glm::vec3 c = glm::vec3(1.0, 1.0, 0.8);
    glm::vec3 p = glm::vec3(0.3f, 0.4f, 0.0f);

    for (const game::Planet *planet : m_state->planets) {
        if (planet->material == game::Planet::Material::Sun) {
            p = glm::vec3(planet->position, 0.0);
            c = planet->getColor();
            break;
        }
    }

    glUniform3f(shader->location("lightPosition"), p.x, p.y, p.z);
    glUniform3f(shader->location("lightColor"), c.x, c.y, c.z);

    std::vector<glm::vec3> positions;
    std::vector<float> intensities;

    size_t numExplLights = 0;

    for (ParticleBatch *batch : m_particles) {
        float age = batch->ageNormalized();
        // TODO: use function with a peak for this:
        //
        //   /\__
        // _/    \--____

        float intensity = 1.0 - age;
        glm::vec3 p = batch->explosionCenter();

        intensities.push_back(intensity);
        positions.push_back(p);

        numExplLights++;

        if (numExplLights == 10) {
            break;
        }
    }

    glUniform1i(shader->location("explLightsNum"), numExplLights);

    if (numExplLights != 0) {
        glUniform3fv(shader->location("explLightsPos"), numExplLights,
                     glm::value_ptr(positions[0]));
        glUniform1fv(shader->location("explLightsIntensities"), numExplLights,
                     intensities.data());
    }
}

void RendererPolygon3d::setWindowSize(int px, int py) {
    m_aspectRatio = (float)px / (float)py;
    m_w = px;
    m_h = py;
}

void RendererPolygon3d::setCameraMatrix(const glm::mat4 &cam) { (void)cam; }
}