coffee-crisis/source/game/entities/balloon.cpp

#include "game/entities/balloon.h"

#include <algorithm>  // for std::max
#include <cmath>      // for std::fabs

#include "core/rendering/animatedsprite.h"  // for AnimatedSprite
#include "core/rendering/movingsprite.h"    // for MovingSprite
#include "core/rendering/sprite.h"          // for Sprite
#include "core/rendering/texture.h"         // for Texture
#include "game/defaults.hpp"                // for PLAY_AREA_LEFT, PLAY_AREA_RIGHT, PLAY_AR...

// Constructor
Balloon::Balloon(float x, float y, Uint8 kind, float velx, float speed, Uint16 creationtimer, Texture *texture, const std::vector<std::string> *animation, SDL_Renderer *renderer) {
    sprite_ = new AnimatedSprite(texture, renderer, "", animation);
    disable();

    enabled_ = true;

    switch (kind) {
        case BALLOON_1:
            width_ = WIDTH_1;
            height_ = WIDTH_1;
            size_ = SIZE_1;
            power_ = 1;

            vel_x_s_ = velx;
            vel_y_s_ = 0.0F;
            max_vel_y_s_ = 180.0F;
            gravity_s_ = 324.0F;
            default_vel_y_s_ = 156.0F;

            score_ = SCORE_1;
            menace_ = 1;
            break;

        case BALLOON_2:
            width_ = WIDTH_2;
            height_ = WIDTH_2;
            size_ = SIZE_2;
            power_ = 3;

            vel_x_s_ = velx;
            vel_y_s_ = 0.0F;
            max_vel_y_s_ = 180.0F;
            gravity_s_ = 360.0F;
            default_vel_y_s_ = 210.0F;

            score_ = SCORE_2;
            menace_ = 2;
            break;

        case BALLOON_3:
            width_ = WIDTH_3;
            height_ = WIDTH_3;
            size_ = SIZE_3;
            power_ = 7;

            vel_x_s_ = velx;
            vel_y_s_ = 0.0F;
            max_vel_y_s_ = 180.0F;
            gravity_s_ = 360.0F;
            default_vel_y_s_ = 270.0F;

            score_ = SCORE_3;
            menace_ = 4;
            break;

        case BALLOON_4:
            width_ = WIDTH_4;
            height_ = WIDTH_4;
            size_ = SIZE_4;
            power_ = 15;

            vel_x_s_ = velx;
            vel_y_s_ = 0.0F;
            max_vel_y_s_ = 180.0F;
            gravity_s_ = 360.0F;
            default_vel_y_s_ = 297.0F;

            score_ = SCORE_4;
            menace_ = 8;
            break;

        case HEXAGON_1:
            width_ = WIDTH_1;
            height_ = WIDTH_1;
            size_ = SIZE_1;
            power_ = 1;

            vel_x_s_ = velx;
            vel_y_s_ = std::fabs(velx) * 2.0F;
            max_vel_y_s_ = std::fabs(velx) * 2.0F;
            gravity_s_ = 0.0F;
            default_vel_y_s_ = std::fabs(velx) * 2.0F;

            score_ = SCORE_1;
            menace_ = 1;
            break;

        case HEXAGON_2:
            width_ = WIDTH_2;
            height_ = WIDTH_2;
            size_ = SIZE_2;
            power_ = 3;

            vel_x_s_ = velx;
            vel_y_s_ = std::fabs(velx) * 2.0F;
            max_vel_y_s_ = std::fabs(velx) * 2.0F;
            gravity_s_ = 0.0F;
            default_vel_y_s_ = std::fabs(velx) * 2.0F;

            score_ = SCORE_2;
            menace_ = 2;
            break;

        case HEXAGON_3:
            width_ = WIDTH_3;
            height_ = WIDTH_3;
            size_ = SIZE_3;
            power_ = 7;

            vel_x_s_ = velx;
            vel_y_s_ = std::fabs(velx) * 2.0F;
            max_vel_y_s_ = std::fabs(velx) * 2.0F;
            gravity_s_ = 0.0F;
            default_vel_y_s_ = std::fabs(velx) * 2.0F;

            score_ = SCORE_3;
            menace_ = 4;
            break;

        case HEXAGON_4:
            width_ = WIDTH_4;
            height_ = WIDTH_4;
            size_ = SIZE_4;
            power_ = 15;

            vel_x_s_ = velx;
            vel_y_s_ = std::fabs(velx) * 2.0F;
            max_vel_y_s_ = std::fabs(velx) * 2.0F;
            gravity_s_ = 0.0F;
            default_vel_y_s_ = std::fabs(velx) * 2.0F;

            score_ = SCORE_4;
            menace_ = 8;
            break;

        case POWER_BALL:
            width_ = WIDTH_4;
            height_ = WIDTH_4;
            size_ = 4;
            power_ = 0;

            vel_x_s_ = velx;
            vel_y_s_ = 0.0F;
            max_vel_y_s_ = 180.0F;
            gravity_s_ = 360.0F;
            default_vel_y_s_ = 297.0F;

            // Puntos que da el globo al ser destruido
            score_ = 0;

            // Amenaza que genera el globo
            menace_ = 0;

            // Configura la rotació del sprite. L'activació/desactivació es
            // delega a `setStop()`, que la sincronitza amb l'estat stopped_
            // sempre que canvia. setRotateSpeed(1) evita la UB del `counter_
            // % 0` dins MovingSprite::rotate().
            sprite_->setRotateSpeed(1);
            sprite_->setRotateAmount(vel_x_s_ > 0.0F ? 2.0 : -2.0);

            break;

        default:
            break;
    }

    // Posición inicial
    pos_x_ = x;
    pos_y_ = y;

    // Valores para el efecto de rebote
    bouncing_.enabled = false;
    bouncing_.counter = 0;
    bouncing_.speed = 2;
    bouncing_.zoom_width = 1.0F;
    bouncing_.zoom_height = 1.0F;
    bouncing_.desp_x = 0.0F;
    bouncing_.desp_y = 0.0F;
    bouncing_.w = {1.10F, 1.05F, 1.00F, 0.95F, 0.90F, 0.95F, 1.00F, 1.02F, 1.05F, 1.02F};
    bouncing_.h = {0.90F, 0.95F, 1.00F, 1.05F, 1.10F, 1.05F, 1.00F, 0.98F, 0.95F, 0.98F};

    // Alto y ancho del sprite
    sprite_->setWidth(width_);
    sprite_->setHeight(height_);

    // Posición X,Y del sprite
    sprite_->setPosX((int)pos_x_);
    sprite_->setPosY((int)pos_y_);

    // Tamaño del circulo de colisión
    collider_.r = width_ / 2;

    // Alinea el circulo de colisión con el objeto
    updateColliders();

    // Inicializa variables
    stopped_ = true;
    stopped_counter_ = 0;
    stopped_counter_s_ = 0.0F;
    blinking_ = false;
    visible_ = true;
    creation_counter_ = creationtimer;
    creation_counter_ini_ = creationtimer;
    creation_counter_s_ = static_cast<float>(creationtimer) / 60.0F;
    creation_counter_ini_s_ = creation_counter_s_;
    creation_phase_s_ = 0.0F;
    bounce_phase_s_ = 0.0F;
    popping_ = false;

    // Valores iniciales dependentes del timer
    being_created_ = creation_counter_ != 0;
    invulnerable_ = being_created_;

    this->speed_ = speed;

    // Tipo
    this->kind_ = kind;
}

// Destructor
Balloon::~Balloon() {
    delete sprite_;
}

// Centra el globo en la posición X
void Balloon::allignTo(int x) {
    pos_x_ = float(x - (width_ / 2));

    if (pos_x_ < PLAY_AREA_LEFT) {
        pos_x_ = PLAY_AREA_LEFT + 1;
    } else if ((pos_x_ + width_) > PLAY_AREA_RIGHT) {
        pos_x_ = float(PLAY_AREA_RIGHT - width_ - 1);
    }

    // Posición X,Y del sprite
    sprite_->setPosX(getPosX());
    sprite_->setPosY(getPosY());

    // Alinea el circulo de colisión con el objeto
    updateColliders();
}

// Pinta el globo en la pantalla
void Balloon::render() {
    if ((visible_) && (enabled_)) {
        if (bouncing_.enabled) {
            if (kind_ != POWER_BALL) {
                // Aplica desplazamiento para el zoom
                sprite_->setPosX(getPosX() + bouncing_.desp_x);
                sprite_->setPosY(getPosY() + bouncing_.desp_y);
                sprite_->render();
                sprite_->setPosX(getPosX() - bouncing_.desp_x);
                sprite_->setPosY(getPosY() - bouncing_.desp_y);
            }
        } else if (isBeingCreated()) {
            // Aplica alpha blending
            sprite_->getTexture()->setAlpha(255 - (int)((float)creation_counter_ * (255.0F / (float)creation_counter_ini_)));
            sprite_->render();
            if (kind_ == POWER_BALL) {
                auto *sp = new Sprite(sprite_->getRect(), sprite_->getTexture(), sprite_->getRenderer());
                sp->setSpriteClip(407, 0, 37, 37);
                sp->render();
                delete sp;
            }
            sprite_->getTexture()->setAlpha(255);
        } else {
            sprite_->render();

            if (kind_ == POWER_BALL and !popping_) {
                auto *sp = new Sprite(sprite_->getRect(), sprite_->getTexture(), sprite_->getRenderer());
                sp->setSpriteClip(407, 0, 37, 37);
                sp->render();
                delete sp;
            }
        }
    }
}

// Actualiza la posición y estados del globo. Integració contínua: gravetat i
// posició s'apliquen escalades per `speed_` (tempo del joc) cada tick.
void Balloon::move(float dt_s) {
    if (!isStopped()) {
        // Eix X
        pos_x_ += vel_x_s_ * speed_ * dt_s;

        if ((pos_x_ < PLAY_AREA_LEFT) || (pos_x_ + width_ > PLAY_AREA_RIGHT)) {
            pos_x_ -= vel_x_s_ * speed_ * dt_s;
            vel_x_s_ = -vel_x_s_;
            sprite_->switchRotate();
            if (kind_ != POWER_BALL) { bounceStart(); }
        }

        // Eix Y
        pos_y_ += vel_y_s_ * speed_ * dt_s;

        if (pos_y_ < PLAY_AREA_TOP) {
            pos_y_ = PLAY_AREA_TOP;
            vel_y_s_ = -vel_y_s_;
            if (kind_ != POWER_BALL) { bounceStart(); }
        }

        if (pos_y_ + height_ > PLAY_AREA_BOTTOM) {
            pos_y_ = PLAY_AREA_BOTTOM - height_;
            vel_y_s_ = -default_vel_y_s_;
            if (kind_ != POWER_BALL) { bounceStart(); }
        }

        // Gravetat contínua (el tempo `speed_` escala també la gravetat).
        vel_y_s_ += gravity_s_ * speed_ * dt_s;

        sprite_->setPosX(getPosX());
        sprite_->setPosY(getPosY());
    }
}

// Deshabilita el globo y pone a cero todos los valores
void Balloon::disable() {
    being_created_ = false;
    blinking_ = false;
    collider_.r = 0;
    collider_.x = 0;
    collider_.y = 0;
    creation_counter_ = 0;
    creation_counter_ini_ = 0;
    creation_counter_s_ = 0.0F;
    creation_counter_ini_s_ = 0.0F;
    creation_phase_s_ = 0.0F;
    bounce_phase_s_ = 0.0F;
    default_vel_y_s_ = 0.0F;
    enabled_ = false;
    gravity_s_ = 0.0F;
    height_ = 0;
    invulnerable_ = false;
    kind_ = 0;
    max_vel_y_s_ = 0.0F;
    menace_ = 0;
    popping_ = false;
    pos_x_ = 0.0F;
    pos_y_ = 0.0F;
    power_ = 0;
    score_ = 0;
    size_ = 0;
    speed_ = 0;
    stopped_ = false;
    stopped_counter_ = 0;
    stopped_counter_s_ = 0.0F;
    vel_x_s_ = 0.0F;
    vel_y_s_ = 0.0F;
    visible_ = false;
    width_ = 0;
    sprite_->clear();
}

// Explosiona el globo
void Balloon::pop() {
    setPopping(true);
    sprite_->disableRotate();
    setStop(true);
    setStoppedTimer(2000);
    setInvulnerable(true);
    menace_ = 0;
}

// Actualiza al globo a su posicion, animación y controla los contadores
void Balloon::update(float dt_s) {
    if (enabled_) {
        // MovingSprite::update(dt_s) avança la rotació (entre altres). La posició
        // del sprite la posa move(dt_s) directament des de pos_x_/pos_y_.
        sprite_->MovingSprite::update(dt_s);
        move(dt_s);
        updateAnimation(dt_s);
        updateColliders();
        updateState(dt_s);
        updateBounce(dt_s);
    }
}

// Actualiza los estados del globo
void Balloon::updateState(float dt_s) {
    if (isPopping()) {
        updateStatePopping();
    }

    if (isBeingCreated()) {
        updateStateBeingCreated(dt_s);
    } else if (isStopped()) {
        updateStateStopped(dt_s);
    }
}

// Rama de updateState: globo explotando
void Balloon::updateStatePopping() {
    setInvulnerable(true);
    setStop(true);
    if (sprite_->animationIsCompleted()) {
        disable();
    }
}

// Rama de updateState: globo creándose. Manté el chunk pattern original:
// cada CREATION_STEP_S s'aplica un step de drift (equivalent a "cada 10
// frames" del codi original). El drift en X usa vel_x_s_/60 per a obtenir
// el mateix delta px-per-step.
void Balloon::updateStateBeingCreated(float dt_s) {
    setStop(true);
    setInvulnerable(true);

    if (creation_counter_s_ > 0.0F) {
        creation_phase_s_ += dt_s;
        while (creation_phase_s_ >= CREATION_STEP_S) {
            creation_phase_s_ -= CREATION_STEP_S;
            pos_y_ += 1.0F;
            const float DRIFT_X = vel_x_s_ / 60.0F;
            pos_x_ += DRIFT_X;

            if ((pos_x_ < PLAY_AREA_LEFT) || (pos_x_ > (PLAY_AREA_RIGHT - width_))) {
                pos_x_ -= DRIFT_X;
                vel_x_s_ = -vel_x_s_;
            }

            sprite_->setPosX(getPosX());
            sprite_->setPosY(getPosY());
            updateColliders();
        }

        creation_counter_s_ = std::max(0.0F, creation_counter_s_ - dt_s);
        creation_counter_ = static_cast<Uint16>(creation_counter_s_ * 60.0F);
    } else {
        setBeingCreated(false);
        setStop(false);
        setVisible(true);
        setInvulnerable(false);
    }
}

// Rama de updateState: globo detenido (no creándose)
void Balloon::updateStateStopped(float dt_s) {
    if (stopped_counter_s_ > 0.0F) {
        stopped_counter_s_ = std::max(0.0F, stopped_counter_s_ - dt_s);
        stopped_counter_ = static_cast<Uint16>(stopped_counter_s_ * 60.0F);
    } else if (!isPopping()) {
        setStop(false);
    }
}

// Establece la animación correspondiente al estado
void Balloon::updateAnimation(float dt_s) {
    std::string creating_animation = "blue";
    std::string normal_animation = "orange";

    if (kind_ == POWER_BALL) {
        creating_animation = "powerball";
        normal_animation = "powerball";
    } else if (getClass() == HEXAGON_CLASS) {
        creating_animation = "red";
        normal_animation = "green";
    }

    if (isPopping()) {
        sprite_->setCurrentAnimation("pop");
    } else if (isBeingCreated()) {
        sprite_->setCurrentAnimation(creating_animation);
    } else {
        sprite_->setCurrentAnimation(normal_animation);
    }

    sprite_->animate(dt_s);
}

// Comprueba si el globo está habilitado
auto Balloon::isEnabled() const -> bool {
    return enabled_;
}

// Obtiene del valor de la variable
auto Balloon::getPosX() const -> float {
    return pos_x_;
}

// Obtiene del valor de la variable
auto Balloon::getPosY() const -> float {
    return pos_y_;
}

// Obtiene del valor de la variable
auto Balloon::getWidth() const -> int {
    return width_;
}

// Obtiene del valor de la variable
auto Balloon::getHeight() const -> int {
    return height_;
}

// Establece el valor de la variable (px/s)
void Balloon::setVelY(float vel_y) {
    this->vel_y_s_ = vel_y;
}

// Establece el valor de la variable
void Balloon::setSpeed(float speed) {
    this->speed_ = speed;
}

// Obtiene del valor de la variable
auto Balloon::getKind() const -> int {
    return kind_;
}

// Obtiene del valor de la variable
auto Balloon::getSize() const -> Uint8 {
    return size_;
}

// Obtiene la clase a la que pertenece el globo
auto Balloon::getClass() const -> Uint8 {
    if ((kind_ >= BALLOON_1) && (kind_ <= BALLOON_4)) {
        return BALLOON_CLASS;
    }

    if ((kind_ >= HEXAGON_1) && (kind_ <= HEXAGON_4)) {
        return HEXAGON_CLASS;
    }

    return BALLOON_CLASS;
}

// Establece el valor de la variable. Per a la PowerBall sincronitza la
// rotació del sprite: stopped=true ⇒ no roda, stopped=false ⇒ roda. Així,
// vingui d'on vingui la crida (FSM intern, Game::stopAll/startAllBalloons,
// fi de creació, etc.), la rotació sempre queda coherent amb l'estat.
void Balloon::setStop(bool state) {
    stopped_ = state;
    if (kind_ == POWER_BALL) {
        sprite_->setRotate(!stopped_);
    }
}

// Obtiene del valor de la variable
auto Balloon::isStopped() const -> bool {
    return stopped_;
}

// Establece el valor de la variable
void Balloon::setBlink(bool value) {
    blinking_ = value;
}

// Obtiene del valor de la variable
auto Balloon::isBlinking() const -> bool {
    return blinking_;
}

// Establece el valor de la variable
void Balloon::setVisible(bool value) {
    visible_ = value;
}

// Obtiene del valor de la variable
auto Balloon::isVisible() const -> bool {
    return visible_;
}

// Establece el valor de la variable
void Balloon::setInvulnerable(bool value) {
    invulnerable_ = value;
}

// Obtiene del valor de la variable
auto Balloon::isInvulnerable() const -> bool {
    return invulnerable_;
}

// Establece el valor de la variable
void Balloon::setBeingCreated(bool value) {
    being_created_ = value;
}

// Obtiene del valor de la variable
auto Balloon::isBeingCreated() const -> bool {
    return being_created_;
}

// Establece el valor de la variable
void Balloon::setPopping(bool value) {
    popping_ = value;
}

// Obtiene del valor de la variable
auto Balloon::isPopping() const -> bool {
    return popping_;
}

// Establece el valor de la variable
void Balloon::setStoppedTimer(Uint16 time) {
    stopped_counter_ = time;
    stopped_counter_s_ = static_cast<float>(time) / 60.0F;
}

// Obtiene del valor de la variable
auto Balloon::getStoppedTimer() const -> Uint16 {
    return stopped_counter_;
}

// Obtiene del valor de la variable
auto Balloon::getScore() const -> Uint16 {
    return score_;
}

// Obtiene el circulo de colisión
auto Balloon::getCollider() -> Circle & {
    return collider_;
}

// Alinea el circulo de colisión con la posición del objeto globo
void Balloon::updateColliders() {
    collider_.x = Uint16(pos_x_ + collider_.r);
    collider_.y = pos_y_ + collider_.r;
}

// Obtiene le valor de la variable
auto Balloon::getMenace() const -> Uint8 {
    if (isEnabled()) {
        return menace_;
    }
    return 0;
}

// Obtiene le valor de la variable
auto Balloon::getPower() const -> Uint8 {
    return power_;
}

void Balloon::bounceStart() {
    bouncing_.enabled = true;
    bouncing_.zoom_width = 1;
    bouncing_.zoom_height = 1;
    sprite_->setZoomW(bouncing_.zoom_width);
    sprite_->setZoomH(bouncing_.zoom_height);
    bouncing_.desp_x = 0;
    bouncing_.desp_y = 0;
}

void Balloon::bounceStop() {
    bouncing_.enabled = false;
    bouncing_.counter = 0;
    bouncing_.zoom_width = 1.0F;
    bouncing_.zoom_height = 1.0F;
    sprite_->setZoomW(bouncing_.zoom_width);
    sprite_->setZoomH(bouncing_.zoom_height);
    bouncing_.desp_x = 0.0F;
    bouncing_.desp_y = 0.0F;
}

void Balloon::updateBounce(float dt_s) {
    if (!bouncing_.enabled) { return; }

    bounce_phase_s_ += dt_s;
    const float STEP_S = static_cast<float>(bouncing_.speed) * BOUNCE_STEP_S;
    while (bounce_phase_s_ >= STEP_S) {
        bounce_phase_s_ -= STEP_S;
        bouncing_.counter++;
    }

    const int IDX = bouncing_.counter / bouncing_.speed;
    if (IDX > (MAX_BOUNCE - 1)) {
        bounceStop();
        bounce_phase_s_ = 0.0F;
        return;
    }

    bouncing_.zoom_width = bouncing_.w[IDX];
    bouncing_.zoom_height = bouncing_.h[IDX];
    sprite_->setZoomW(bouncing_.zoom_width);
    sprite_->setZoomH(bouncing_.zoom_height);
    bouncing_.desp_x = (sprite_->getSpriteClip().w - (sprite_->getSpriteClip().w * bouncing_.zoom_width));
    bouncing_.desp_y = (sprite_->getSpriteClip().h - (sprite_->getSpriteClip().h * bouncing_.zoom_height));
}