// ----------------------------------------------------------------------------
bool KartProperties::operator<(const KartProperties &other) const
{
PlayerProfile *p = PlayerManager::getCurrentPlayer();
bool this_is_locked = p->isLocked(getIdent());
bool other_is_locked = p->isLocked(other.getIdent());
if (this_is_locked == other_is_locked)
{
return getName() < other.getName();
}
else
return other_is_locked;
return true;
} // operator<
/** Returns a unique identifier for this kart (name of the directory the
* kart was loaded from). */
const std::string& getIdent() const {return m_kart_properties->getIdent();}
/** Returns a name to be displayed for this kart. */
virtual const irr::core::stringw& getName() const
{ return m_kart_properties->getName(); }
/** Returns the maximum steering angle for this kart, which depends on the
* speed. */
float getMaxSteerAngle () const
{ return m_kart_properties->getMaxSteerAngle(getSpeed()); }
/** Returns the time till full steering is reached for this kart. */
float getTimeFullSteer() const
{ return m_kart_properties->getTimeFullSteer(); }
/** Returns the strenght of the brakes for this kart. */
float getBrakeFactor() const {return m_kart_properties->getBrakeFactor();}
/** Returns the maximum engine power for this kart. */
float getMaxPower () const {return m_kart_properties->getMaxPower(); }
/** Returns the current mass of this kart, including any attachment this
* kart might have. */
float getMass() const { return m_kart_properties->getMass()
+ m_attachment->weightAdjust();}
/** Returns the color used for this kart. */
const video::SColor &getColor() const
{return m_kart_properties->getColor();}
/** Sets that the view is blocked by a plunger. The duration depends on
* the difficulty, see KartPorperties getPlungerInFaceTime. */
void blockViewWithPlunger()
{ m_view_blocked_by_plunger =
m_kart_properties->getPlungerInFaceTime();}
/** Loads the 3d model and all wheels.
*/
bool KartModel::loadModels(const KartProperties &kart_properties)
{
assert(m_is_master);
std::string full_path = kart_properties.getKartDir()+m_model_filename;
m_mesh = irr_driver->getAnimatedMesh(full_path);
if(!m_mesh)
{
Log::error("Kart_Model", "Problems loading mesh '%s' - kart '%s' will"
"not be available.",
full_path.c_str(), kart_properties.getIdent().c_str());
return false;
}
m_mesh->grab();
irr_driver->grabAllTextures(m_mesh);
Vec3 kart_min, kart_max;
MeshTools::minMax3D(m_mesh->getMesh(m_animation_frame[AF_STRAIGHT]),
&kart_min, &kart_max);
// Test if kart model support colorization
for (u32 i = 0; i < m_mesh->getMeshBufferCount(); i++)
{
scene::IMeshBuffer* mb = m_mesh->getMeshBuffer(i);
Material* material = material_manager->getMaterialFor(mb
->getMaterial().getTexture(0), mb);
m_support_colorization =
m_support_colorization || material->isColorizable();
}
#undef MOVE_KART_MESHES
#ifdef MOVE_KART_MESHES
// Kart models are not exactly centered. The following code would
// transform the mesh so that they are properly centered, but it
// would also mean all location relative to the original kart's
// center (wheel position, emitter, hat) would need to be modified.
scene::IMeshManipulator *mani =
irr_driver->getVideoDriver()->getMeshManipulator();
Vec3 offset_from_center = -0.5f*(kart_max+kart_min);
offset_from_center.setY(-kart_min.getY());
offset_from_center.setY(0);
core::matrix4 translate(core::matrix4::EM4CONST_IDENTITY);
translate.setTranslation(offset_from_center.toIrrVector());
mani->transform(m_mesh, translate);
MeshTools::minMax3D(m_mesh->getMesh(m_animation_frame[AF_STRAIGHT]),
&kart_min, &kart_max);
#endif
m_kart_highest_point = kart_max.getY();
m_kart_lowest_point = kart_min.getY();
// Load the speed weighted object models. We need to do that now because it can affect the dimensions of the kart
for(size_t i=0 ; i < m_speed_weighted_objects.size() ; i++)
{
SpeedWeightedObject& obj = m_speed_weighted_objects[i];
std::string full_name =
kart_properties.getKartDir()+obj.m_name;
obj.m_model = irr_driver->getAnimatedMesh(full_name);
// Grab all textures. This is done for the master only, so
// the destructor will only free the textures if a master
// copy is freed.
irr_driver->grabAllTextures(obj.m_model);
// Update min/max
Vec3 obj_min, obj_max;
MeshTools::minMax3D(obj.m_model, &obj_min, &obj_max);
obj_min += obj.m_position;
obj_max += obj.m_position;
kart_min.min(obj_min);
kart_max.max(obj_max);
}
Vec3 size = kart_max-kart_min;
m_kart_width = size.getX();
m_kart_height = size.getY();
m_kart_length = size.getZ();
// Now set default some default parameters (if not defined) that
// depend on the size of the kart model (wheel position, center
// of gravity shift)
for(unsigned int i=0; i<4; i++)
{
if(m_wheel_graphics_position[i].getX()==UNDEFINED)
{
m_wheel_graphics_position[i].setX( ( i==1||i==3)
? -0.5f*m_kart_width
: 0.5f*m_kart_width );
m_wheel_graphics_position[i].setY(0);
m_wheel_graphics_position[i].setZ( (i<2) ? 0.5f*m_kart_length
: -0.5f*m_kart_length);
}
}
// Load the wheel models. This can't be done early, since the default
// values for the graphical position must be defined, which in turn
// depend on the size of the model.
for(unsigned int i=0; i<4; i++)
{
// For kart models without wheels.
if(m_wheel_filename[i]=="") continue;
std::string full_wheel =
kart_properties.getKartDir()+m_wheel_filename[i];
m_wheel_model[i] = irr_driver->getMesh(full_wheel);
// Grab all textures. This is done for the master only, so
// the destructor will only free the textures if a master
// copy is freed.
irr_driver->grabAllTextures(m_wheel_model[i]);
} // for i<4
return true;
} // loadModels
/** Returns a name to be displayed for this kart. */
virtual const wchar_t* getName() const
{ return m_kart_properties->getName(); }
