C++ (Cpp) getLinearKartItemIntersection примеры использования

Язык программирования: C++ (Cpp)

Метод/Функция: getLinearKartItemIntersection

Примеров на hotexamples.com: 2

C++ (Cpp) getLinearKartItemIntersection - 2 примера найдено. Это лучшие примеры C++ (Cpp) кода для getLinearKartItemIntersection, полученные из open source проектов. Вы можете ставить оценку каждому примеру, чтобы помочь нам улучшить качество примеров.

Пример #1

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Файл: plunger.cpp Проект: rugk/stk-code

// -----------------------------------------------------------------------------
Plunger::Plunger(AbstractKart *kart)
       : Flyable(kart, PowerupManager::POWERUP_PLUNGER)
{
    const float gravity = 0.0f;

    float forward_offset = 0.5f*kart->getKartLength()+0.5f*m_extend.getZ();
    float up_velocity = 0.0f;
    float plunger_speed = 2 * m_speed;

    // if the kart is looking backwards, release from the back
    m_reverse_mode = kart->getControls().m_look_back;

    // find closest kart in front of the current one
    const AbstractKart *closest_kart=0;
    Vec3        direction;
    float       kart_dist_2;
    getClosestKart(&closest_kart, &kart_dist_2, &direction,
                   kart /* search in front of this kart */, m_reverse_mode);

    btTransform kart_transform = kart->getAlignedTransform();
    btMatrix3x3 kart_rotation = kart_transform.getBasis();

    float heading =kart->getHeading();
    float pitch  = kart->getTerrainPitch(heading);

    // aim at this kart if it's not too far
    if(closest_kart != NULL && kart_dist_2 < 30*30)
    {
        float fire_angle     = 0.0f;
        getLinearKartItemIntersection (kart->getXYZ(), closest_kart,
                                       plunger_speed, gravity, forward_offset,
                                       &fire_angle, &up_velocity);

        btTransform trans = kart->getTrans();

        trans.setRotation(btQuaternion(btVector3(0, 1, 0), fire_angle));

        m_initial_velocity = btVector3(0.0f, up_velocity, plunger_speed);

        createPhysics(forward_offset, m_initial_velocity,
                      new btCylinderShape(0.5f*m_extend),
                      0.5f /* restitution */ , gravity,
                      /* rotates */false , /*turn around*/false, &trans);
    }
    else
    {
        createPhysics(forward_offset, btVector3(pitch, 0.0f, plunger_speed),
                      new btCylinderShape(0.5f*m_extend),
                      0.5f /* restitution */, gravity,
                      false /* rotates */, m_reverse_mode, &kart_transform);
    }

    //adjust height according to terrain
    setAdjustUpVelocity(false);

    // pulling back makes no sense in battle mode, since this mode is not a race.
    // so in battle mode, always hide view
    if( m_reverse_mode || race_manager->isBattleMode() )
        m_rubber_band = NULL;
    else
    {
        m_rubber_band = new RubberBand(this, kart);
    }
    m_keep_alive = -1;
}   // Plunger

Пример #2

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Файл: cake.cpp Проект: AkshayGupta94/stk-code

Cake::Cake (AbstractKart *kart) : Flyable(kart, PowerupManager::POWERUP_CAKE)
{
    m_target = NULL;

    // A bit of a hack: the mass of this kinematic object is still 1.0
    // (see flyable), which enables collisions. I tried setting
    // collisionFilterGroup/mask, but still couldn't get this object to
    // collide with the track. By setting the mass to 1, collisions happen.
    // (if bullet is compiled with _DEBUG, a warning will be printed the first
    // time a homing-track collision happens).
    float forward_offset=kart->getKartLength()/2.0f + m_extend.getZ()/2.0f;

    float up_velocity = m_speed/7.0f;

    // give a speed proportional to kart speed. m_speed is defined in flyable
    m_speed *= kart->getSpeed() / 23.0f;

    //when going backwards, decrease speed of cake by less
    if (kart->getSpeed() < 0) m_speed /= 3.6f;

    m_speed += 16.0f;

    if (m_speed < 1.0f) m_speed = 1.0f;

    btTransform trans = kart->getTrans();

    float heading=kart->getHeading();
    float pitch = kart->getTerrainPitch(heading);

    // Find closest kart in front of the current one
    const bool  backwards = kart->getControls().m_look_back;
    const AbstractKart *closest_kart=NULL;
    Vec3        direction;
    float       kart_dist_squared;
    getClosestKart(&closest_kart, &kart_dist_squared, &direction,
                   kart /* search in front of this kart */, backwards);

    // aim at this kart if 1) it's not too far, 2) if the aimed kart's speed
    // allows the projectile to catch up with it
    //
    // this code finds the correct angle and upwards velocity to hit an opponents'
    // vehicle if they were to continue travelling in the same direction and same speed
    // (barring any obstacles in the way of course)
    if(closest_kart != NULL && kart_dist_squared < m_st_max_distance_squared &&
        m_speed>closest_kart->getSpeed())
    {
        m_target = (AbstractKart*)closest_kart;

        float fire_angle     = 0.0f;
        getLinearKartItemIntersection (kart->getXYZ(), closest_kart,
                                       m_speed, m_gravity, forward_offset,
                                       &fire_angle, &up_velocity);

        // apply transformation to the bullet object (without pitch)
        trans.setRotation(btQuaternion(btVector3(0,1,0), fire_angle));

        m_initial_velocity = Vec3(0.0f, up_velocity, m_speed);

        createPhysics(forward_offset, m_initial_velocity,
                      new btCylinderShape(0.5f*m_extend),
                      0.5f /* restitution */, -m_gravity,
                      true /* rotation */, false /* backwards */, &trans);
    }
    else
    {
        m_target = NULL;
        // kart is too far to be hit. so throw the projectile in a generic way,
        // straight ahead, without trying to hit anything in particular
        trans = kart->getAlignedTransform(pitch);

        m_initial_velocity = Vec3(0.0f, up_velocity, m_speed);

        createPhysics(forward_offset, m_initial_velocity,
                      new btCylinderShape(0.5f*m_extend),
                      0.5f /* restitution */, -m_gravity,
                      true /* rotation */, backwards, &trans);
    }


    //do not adjust height according to terrain
    setAdjustUpVelocity(false);

    m_body->setActivationState(DISABLE_DEACTIVATION);

    m_body->applyTorque( btVector3(5,-3,7) );

}   // Cake