fysxasteroids/engine/PhysicsEntityBase.cc

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2010-04-05 23:38:59 +02:00
#include "EntityBase.h"
#include "coll2d.h"
namespace Engine {
/** \brief Copy constructor */
inline EntityPhysicState::EntityPhysicState (const EntityPhysicState& state):
mId (state.mId),
mBaseType (state.mBaseType),
mPosition (state.mPosition),
mOrientation (state.mOrientation),
mVelocity (state.mVelocity),
mAngleVelocity (state.mAngleVelocity),
mStatic (state.mStatic),
mAlive (state.mAlive),
mContactNormals(state.mContactNormals)
{
mShape = state.mShape->getCopy();
};
/** \brief Assignment operator */
inline EntityPhysicState& EntityPhysicState::operator= (const EntityPhysicState& state) {
if (this != &state) {
mId = state.mId;
mBaseType = state.mBaseType;
mPosition = state.mPosition;
mOrientation = state.mOrientation;
mVelocity = state.mVelocity;
mAngleVelocity = state.mAngleVelocity;
mShape = state.mShape->getCopy();
mStatic = state.mStatic;
mAlive = state.mAlive;
mContactNormals = state.mContactNormals;
}
return *this;
}
vector3d& EntityPhysicState::GetPosition () {
return mPosition;
}
vector3d& EntityPhysicState::GetVelocity () {
return mVelocity;
}
vector3d& EntityPhysicState::GetOrientation () {
return mOrientation;
}
float& EntityPhysicState::GetAngleVelocity () {
return mAngleVelocity;
}
void EntityPhysicState::Globalize (vector3d &vec) {
// make a copy of the local coordinates
vector3d local (vec);
// calculate sin and cos for the current rotation
float sintheta, costheta;
sintheta = sin (- mOrientation[1] * M_PI / 180);
costheta = cos (- mOrientation[1] * M_PI / 180);
// rotation
vec[0] = - sintheta * local[2] + costheta * local[0];
vec[1] = local[1];
vec[2] = costheta * local[2] + sintheta * local[0] ;
// and translation
vec += mPosition;
}
void EntityPhysicState::Localize (vector3d &vec) {
// translation
vec -= mPosition;
vector3d global (vec);
// calculate sin and cos for the current rotation
float sintheta, costheta;
sintheta = sin (mOrientation[1] * M_PI / 180);
costheta = cos (mOrientation[1] * M_PI / 180);
// rotation
vec[0] = - sintheta * global[2] + costheta * global[0];
vec[1] = global[1];
vec[2] = costheta * global[2] + sintheta * global[0] ;
}
void EntityPhysicState::GlobalizeRotation (vector3d &vec) {
// make a copy of the local coordinates
vector3d local (vec);
// calculate sin and cos for the current rotation
float sintheta, costheta;
sintheta = sin (- mOrientation[1] * M_PI / 180);
costheta = cos (- mOrientation[1] * M_PI / 180);
// rotation
vec[0] = - sintheta * local[2] + costheta * local[0];
vec[1] = local[1];
vec[2] = costheta * local[2] + sintheta * local[0] ;
}
void EntityPhysicState::LocalizeRotation (vector3d &vec) {
vector3d global (vec);
// calculate sin and cos for the current rotation
float sintheta, costheta;
sintheta = sin (mOrientation[1] * M_PI / 180);
costheta = cos (mOrientation[1] * M_PI / 180);
// rotation
vec[0] = - sintheta * global[2] + costheta * global[0];
vec[1] = global[1];
vec[2] = costheta * global[2] + sintheta * global[0] ;
}
void EntityPhysicState::UpdateShape () {
assert (mShape);
mShape->setPosition (mPosition);
mShape->setAngle (mOrientation[1] * M_PI / 180);
mShape->setVelocity (mVelocity);
mShape->setAngleVelocity (mAngleVelocity);
}
}