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Added BulletCharacter Dummy code.

legacy
Benjamin ‘Touky’ Huet touky před 12 roky
rodič
revize
100119a07b
2 změnil soubory, kde provedl 764 přidání a 0 odebrání
  1. +136
    -0
      test/Physics/Include/BulletCharacterController.h
  2. +628
    -0
      test/Physics/Src/BulletCharacterController.cpp

+ 136
- 0
test/Physics/Include/BulletCharacterController.h Zobrazit soubor

@@ -21,6 +21,7 @@
#ifdef HAVE_PHYS_USE_BULLET
#include "core.h"
#include "EasyPhysics.h"
//#include "BulletDynamics\Character\btCharacterControllerInterface.h"
#endif

namespace lol
@@ -29,6 +30,141 @@ namespace lol
namespace phys
{

#define 0
#ifdef HAVE_PHYS_USE_BULLET

///BulletKinematicCharacterController is an object that supports a sliding motion in a world.
///It uses a ghost object and convex sweep test to test for upcoming collisions. This is combined with discrete collision detection to recover from penetrations.
///Interaction between btKinematicCharacterController and dynamic rigid bodies needs to be explicity implemented by the user.
class BulletKinematicCharacterController : public btCharacterControllerInterface
{
protected:

btScalar m_halfHeight;

btPairCachingGhostObject* m_ghostObject;
btConvexShape* m_convexShape;//is also in m_ghostObject, but it needs to be convex, so we store it here to avoid upcast

btScalar m_verticalVelocity;
btScalar m_verticalOffset;
btScalar m_fallSpeed;
btScalar m_jumpSpeed;
btScalar m_maxJumpHeight;
btScalar m_maxSlopeRadians; // Slope angle that is set (used for returning the exact value)
btScalar m_maxSlopeCosine; // Cosine equivalent of m_maxSlopeRadians (calculated once when set, for optimization)
btScalar m_gravity;

btScalar m_turnAngle;

btScalar m_stepHeight;

btScalar m_addedMargin;//@todo: remove this and fix the code

///this is the desired walk direction, set by the user
btVector3 m_walkDirection;
btVector3 m_normalizedDirection;

//some internal variables
btVector3 m_currentPosition;
btScalar m_currentStepOffset;
btVector3 m_targetPosition;

///keep track of the contact manifolds
btManifoldArray m_manifoldArray;

bool m_touchingContact;
btVector3 m_touchingNormal;

bool m_wasOnGround;
bool m_wasJumping;
bool m_useGhostObjectSweepTest;
bool m_useWalkDirection;
btScalar m_velocityTimeInterval;
int m_upAxis;

static btVector3* getUpAxisDirections();

btVector3 computeReflectionDirection (const btVector3& direction, const btVector3& normal);
btVector3 parallelComponent (const btVector3& direction, const btVector3& normal);
btVector3 perpindicularComponent (const btVector3& direction, const btVector3& normal);

bool recoverFromPenetration ( btCollisionWorld* collisionWorld);
void stepUp (btCollisionWorld* collisionWorld);
void updateTargetPositionBasedOnCollision (const btVector3& hit_normal, btScalar tangentMag = btScalar(0.0), btScalar normalMag = btScalar(1.0));
void stepForwardAndStrafe (btCollisionWorld* collisionWorld, const btVector3& walkMove);
void stepDown (btCollisionWorld* collisionWorld, btScalar dt);
public:
BulletKinematicCharacterController (btPairCachingGhostObject* ghostObject,btConvexShape* convexShape,btScalar stepHeight, int upAxis = 1);
~BulletKinematicCharacterController ();


///btActionInterface interface
virtual void updateAction( btCollisionWorld* collisionWorld,btScalar deltaTime)
{
preStep ( collisionWorld);
playerStep (collisionWorld, deltaTime);
}

///btActionInterface interface
void debugDraw(btIDebugDraw* debugDrawer);

void setUpAxis (int axis)
{
if (axis < 0)
axis = 0;
if (axis > 2)
axis = 2;
m_upAxis = axis;
}

/// This should probably be called setPositionIncrementPerSimulatorStep.
/// This is neither a direction nor a velocity, but the amount to
/// increment the position each simulation iteration, regardless
/// of dt.
/// This call will reset any velocity set by setVelocityForTimeInterval().
virtual void setWalkDirection(const btVector3& walkDirection);

/// Caller provides a velocity with which the character should move for
/// the given time period. After the time period, velocity is reset
/// to zero.
/// This call will reset any walk direction set by setWalkDirection().
/// Negative time intervals will result in no motion.
virtual void setVelocityForTimeInterval(const btVector3& velocity,
btScalar timeInterval);

void reset ();
void warp (const btVector3& origin);

void preStep ( btCollisionWorld* collisionWorld);
void playerStep ( btCollisionWorld* collisionWorld, btScalar dt);

void setFallSpeed (btScalar fallSpeed);
void setJumpSpeed (btScalar jumpSpeed);
void setMaxJumpHeight (btScalar maxJumpHeight);
bool canJump () const;

void jump ();

void setGravity(btScalar gravity);
btScalar getGravity() const;

/// The max slope determines the maximum angle that the controller can walk up.
/// The slope angle is measured in radians.
void setMaxSlope(btScalar slopeRadians);
btScalar getMaxSlope() const;

btPairCachingGhostObject* getGhostObject();
void setUseGhostSweepTest(bool useGhostObjectSweepTest)
{
m_useGhostObjectSweepTest = useGhostObjectSweepTest;
}

bool onGround () const;
};

#endif // HAVE_PHYS_USE_BULLET
#endif // 0

} /* namespace phys */

} /* namespace lol */


+ 628
- 0
test/Physics/Src/BulletCharacterController.cpp Zobrazit soubor

@@ -17,6 +17,15 @@
#include "../Include/LolBtPhysicsIntegration.h"
#include "../Include/LolPhysics.h"
#include "../Include/EasyCharacterController.h"
#include "../Include/BulletCharacterController.h"
//#include "LinearMath/btIDebugDraw.h"
//#include "BulletCollision/CollisionDispatch/btGhostObject.h"
//#include "BulletCollision/CollisionShapes/btMultiSphereShape.h"
//#include "BulletCollision/BroadphaseCollision/btOverlappingPairCache.h"
//#include "BulletCollision/BroadphaseCollision/btCollisionAlgorithm.h"
//#include "BulletCollision/CollisionDispatch/btCollisionWorld.h"
//#include "LinearMath/btDefaultMotionState.h"


namespace lol
{
@@ -24,9 +33,628 @@ namespace lol
namespace phys
{

#define 0
#ifdef HAVE_PHYS_USE_BULLET

// static helper method
static btVector3
getNormalizedVector(const btVector3& v)
{
btVector3 n = v.normalized();
if (n.length() < SIMD_EPSILON) {
n.setValue(0, 0, 0);
}
return n;
}


///@todo Interact with dynamic objects,
///Ride kinematicly animated platforms properly
///More realistic (or maybe just a config option) falling
/// -> Should integrate falling velocity manually and use that in stepDown()
///Support jumping
///Support ducking
class btKinematicClosestNotMeRayResultCallback : public btCollisionWorld::ClosestRayResultCallback
{
public:
btKinematicClosestNotMeRayResultCallback (btCollisionObject* me) : btCollisionWorld::ClosestRayResultCallback(btVector3(0.0, 0.0, 0.0), btVector3(0.0, 0.0, 0.0))
{
m_me = me;
}

virtual btScalar addSingleResult(btCollisionWorld::LocalRayResult& rayResult,bool normalInWorldSpace)
{
if (rayResult.m_collisionObject == m_me)
return 1.0;

return ClosestRayResultCallback::addSingleResult (rayResult, normalInWorldSpace);
}
protected:
btCollisionObject* m_me;
};

class btKinematicClosestNotMeConvexResultCallback : public btCollisionWorld::ClosestConvexResultCallback
{
public:
btKinematicClosestNotMeConvexResultCallback (btCollisionObject* me, const btVector3& up, btScalar minSlopeDot)
: btCollisionWorld::ClosestConvexResultCallback(btVector3(0.0, 0.0, 0.0), btVector3(0.0, 0.0, 0.0))
, m_me(me)
, m_up(up)
, m_minSlopeDot(minSlopeDot)
{
}

virtual btScalar addSingleResult(btCollisionWorld::LocalConvexResult& convexResult,bool normalInWorldSpace)
{
if (convexResult.m_hitCollisionObject == m_me)
return btScalar(1.0);

btVector3 hitNormalWorld;
if (normalInWorldSpace)
{
hitNormalWorld = convexResult.m_hitNormalLocal;
} else
{
///need to transform normal into worldspace
hitNormalWorld = convexResult.m_hitCollisionObject->getWorldTransform().getBasis()*convexResult.m_hitNormalLocal;
}

btScalar dotUp = m_up.dot(hitNormalWorld);
if (dotUp < m_minSlopeDot) {
return btScalar(1.0);
}

return ClosestConvexResultCallback::addSingleResult (convexResult, normalInWorldSpace);
}
protected:
btCollisionObject* m_me;
const btVector3 m_up;
btScalar m_minSlopeDot;
};

/*
* Returns the reflection direction of a ray going 'direction' hitting a surface with normal 'normal'
*
* from: http://www-cs-students.stanford.edu/~adityagp/final/node3.html
*/
btVector3 BulletKinematicCharacterController::computeReflectionDirection (const btVector3& direction, const btVector3& normal)
{
return direction - (btScalar(2.0) * direction.dot(normal)) * normal;
}

/*
* Returns the portion of 'direction' that is parallel to 'normal'
*/
btVector3 BulletKinematicCharacterController::parallelComponent (const btVector3& direction, const btVector3& normal)
{
btScalar magnitude = direction.dot(normal);
return normal * magnitude;
}

/*
* Returns the portion of 'direction' that is perpindicular to 'normal'
*/
btVector3 BulletKinematicCharacterController::perpindicularComponent (const btVector3& direction, const btVector3& normal)
{
return direction - parallelComponent(direction, normal);
}

BulletKinematicCharacterController::BulletKinematicCharacterController (btPairCachingGhostObject* ghostObject,btConvexShape* convexShape,btScalar stepHeight, int upAxis)
{
m_upAxis = upAxis;
m_addedMargin = 0.02;
m_walkDirection.setValue(0,0,0);
m_useGhostObjectSweepTest = true;
m_ghostObject = ghostObject;
m_stepHeight = stepHeight;
m_turnAngle = btScalar(0.0);
m_convexShape=convexShape;
m_useWalkDirection = true; // use walk direction by default, legacy behavior
m_velocityTimeInterval = 0.0;
m_verticalVelocity = 0.0;
m_verticalOffset = 0.0;
m_gravity = 9.8 * 3 ; // 3G acceleration.
m_fallSpeed = 55.0; // Terminal velocity of a sky diver in m/s.
m_jumpSpeed = 10.0; // ?
m_wasOnGround = false;
m_wasJumping = false;
setMaxSlope(btRadians(45.0));
}

BulletKinematicCharacterController::~BulletKinematicCharacterController ()
{
}

btPairCachingGhostObject* BulletKinematicCharacterController::getGhostObject()
{
return m_ghostObject;
}

bool BulletKinematicCharacterController::recoverFromPenetration ( btCollisionWorld* collisionWorld)
{

bool penetration = false;

collisionWorld->getDispatcher()->dispatchAllCollisionPairs(m_ghostObject->getOverlappingPairCache(), collisionWorld->getDispatchInfo(), collisionWorld->getDispatcher());

m_currentPosition = m_ghostObject->getWorldTransform().getOrigin();
btScalar maxPen = btScalar(0.0);
for (int i = 0; i < m_ghostObject->getOverlappingPairCache()->getNumOverlappingPairs(); i++)
{
m_manifoldArray.resize(0);

btBroadphasePair* collisionPair = &m_ghostObject->getOverlappingPairCache()->getOverlappingPairArray()[i];
if (collisionPair->m_algorithm)
collisionPair->m_algorithm->getAllContactManifolds(m_manifoldArray);

for (int j=0;j<m_manifoldArray.size();j++)
{
btPersistentManifold* manifold = m_manifoldArray[j];
btScalar directionSign = manifold->getBody0() == m_ghostObject ? btScalar(-1.0) : btScalar(1.0);
for (int p=0;p<manifold->getNumContacts();p++)
{
const btManifoldPoint&pt = manifold->getContactPoint(p);

btScalar dist = pt.getDistance();

if (dist < 0.0)
{
if (dist < maxPen)
{
maxPen = dist;
m_touchingNormal = pt.m_normalWorldOnB * directionSign;//??

}
m_currentPosition += pt.m_normalWorldOnB * directionSign * dist * btScalar(0.2);
penetration = true;
} else {
//printf("touching %f\n", dist);
}
}
//manifold->clearManifold();
}
}
btTransform newTrans = m_ghostObject->getWorldTransform();
newTrans.setOrigin(m_currentPosition);
m_ghostObject->setWorldTransform(newTrans);
// printf("m_touchingNormal = %f,%f,%f\n",m_touchingNormal[0],m_touchingNormal[1],m_touchingNormal[2]);
return penetration;
}

void BulletKinematicCharacterController::stepUp ( btCollisionWorld* world)
{
// phase 1: up
btTransform start, end;
m_targetPosition = m_currentPosition + getUpAxisDirections()[m_upAxis] * (m_stepHeight + (m_verticalOffset > 0.f?m_verticalOffset:0.f));

start.setIdentity ();
end.setIdentity ();

/* FIXME: Handle penetration properly */
start.setOrigin (m_currentPosition + getUpAxisDirections()[m_upAxis] * (m_convexShape->getMargin() + m_addedMargin));
end.setOrigin (m_targetPosition);

btKinematicClosestNotMeConvexResultCallback callback (m_ghostObject, -getUpAxisDirections()[m_upAxis], btScalar(0.7071));
callback.m_collisionFilterGroup = getGhostObject()->getBroadphaseHandle()->m_collisionFilterGroup;
callback.m_collisionFilterMask = getGhostObject()->getBroadphaseHandle()->m_collisionFilterMask;
if (m_useGhostObjectSweepTest)
{
m_ghostObject->convexSweepTest (m_convexShape, start, end, callback, world->getDispatchInfo().m_allowedCcdPenetration);
}
else
{
world->convexSweepTest (m_convexShape, start, end, callback);
}
if (callback.hasHit())
{
// Only modify the position if the hit was a slope and not a wall or ceiling.
if(callback.m_hitNormalWorld.dot(getUpAxisDirections()[m_upAxis]) > 0.0)
{
// we moved up only a fraction of the step height
m_currentStepOffset = m_stepHeight * callback.m_closestHitFraction;
m_currentPosition.setInterpolate3 (m_currentPosition, m_targetPosition, callback.m_closestHitFraction);
}
m_verticalVelocity = 0.0;
m_verticalOffset = 0.0;
} else {
m_currentStepOffset = m_stepHeight;
m_currentPosition = m_targetPosition;
}
}

void BulletKinematicCharacterController::updateTargetPositionBasedOnCollision (const btVector3& hitNormal, btScalar tangentMag, btScalar normalMag)
{
btVector3 movementDirection = m_targetPosition - m_currentPosition;
btScalar movementLength = movementDirection.length();
if (movementLength>SIMD_EPSILON)
{
movementDirection.normalize();

btVector3 reflectDir = computeReflectionDirection (movementDirection, hitNormal);
reflectDir.normalize();

btVector3 parallelDir, perpindicularDir;

parallelDir = parallelComponent (reflectDir, hitNormal);
perpindicularDir = perpindicularComponent (reflectDir, hitNormal);

m_targetPosition = m_currentPosition;
if (0)//tangentMag != 0.0)
{
btVector3 parComponent = parallelDir * btScalar (tangentMag*movementLength);
// printf("parComponent=%f,%f,%f\n",parComponent[0],parComponent[1],parComponent[2]);
m_targetPosition += parComponent;
}

if (normalMag != 0.0)
{
btVector3 perpComponent = perpindicularDir * btScalar (normalMag*movementLength);
// printf("perpComponent=%f,%f,%f\n",perpComponent[0],perpComponent[1],perpComponent[2]);
m_targetPosition += perpComponent;
}
} else
{
// printf("movementLength don't normalize a zero vector\n");
}
}

void BulletKinematicCharacterController::stepForwardAndStrafe ( btCollisionWorld* collisionWorld, const btVector3& walkMove)
{
// printf("m_normalizedDirection=%f,%f,%f\n",
// m_normalizedDirection[0],m_normalizedDirection[1],m_normalizedDirection[2]);
// phase 2: forward and strafe
btTransform start, end;
m_targetPosition = m_currentPosition + walkMove;

start.setIdentity ();
end.setIdentity ();
btScalar fraction = 1.0;
btScalar distance2 = (m_currentPosition-m_targetPosition).length2();
// printf("distance2=%f\n",distance2);

if (m_touchingContact)
{
if (m_normalizedDirection.dot(m_touchingNormal) > btScalar(0.0))
{
updateTargetPositionBasedOnCollision (m_touchingNormal);
}
}

int maxIter = 10;

while (fraction > btScalar(0.01) && maxIter-- > 0)
{
start.setOrigin (m_currentPosition);
end.setOrigin (m_targetPosition);
btVector3 sweepDirNegative(m_currentPosition - m_targetPosition);

btKinematicClosestNotMeConvexResultCallback callback (m_ghostObject, sweepDirNegative, btScalar(0.0));
callback.m_collisionFilterGroup = getGhostObject()->getBroadphaseHandle()->m_collisionFilterGroup;
callback.m_collisionFilterMask = getGhostObject()->getBroadphaseHandle()->m_collisionFilterMask;


btScalar margin = m_convexShape->getMargin();
m_convexShape->setMargin(margin + m_addedMargin);


if (m_useGhostObjectSweepTest)
{
m_ghostObject->convexSweepTest (m_convexShape, start, end, callback, collisionWorld->getDispatchInfo().m_allowedCcdPenetration);
} else
{
collisionWorld->convexSweepTest (m_convexShape, start, end, callback, collisionWorld->getDispatchInfo().m_allowedCcdPenetration);
}
m_convexShape->setMargin(margin);

fraction -= callback.m_closestHitFraction;

if (callback.hasHit())
{
// we moved only a fraction
btScalar hitDistance;
hitDistance = (callback.m_hitPointWorld - m_currentPosition).length();

// m_currentPosition.setInterpolate3 (m_currentPosition, m_targetPosition, callback.m_closestHitFraction);

updateTargetPositionBasedOnCollision (callback.m_hitNormalWorld);
btVector3 currentDir = m_targetPosition - m_currentPosition;
distance2 = currentDir.length2();
if (distance2 > SIMD_EPSILON)
{
currentDir.normalize();
/* See Quake2: "If velocity is against original velocity, stop ead to avoid tiny oscilations in sloping corners." */
if (currentDir.dot(m_normalizedDirection) <= btScalar(0.0))
{
break;
}
} else
{
// printf("currentDir: don't normalize a zero vector\n");
break;
}

} else {
// we moved whole way
m_currentPosition = m_targetPosition;
}

// if (callback.m_closestHitFraction == 0.f)
// break;

}
}

void BulletKinematicCharacterController::stepDown ( btCollisionWorld* collisionWorld, btScalar dt)
{
btTransform start, end;

// phase 3: down
/*btScalar additionalDownStep = (m_wasOnGround && !onGround()) ? m_stepHeight : 0.0;
btVector3 step_drop = getUpAxisDirections()[m_upAxis] * (m_currentStepOffset + additionalDownStep);
btScalar downVelocity = (additionalDownStep == 0.0 && m_verticalVelocity<0.0?-m_verticalVelocity:0.0) * dt;
btVector3 gravity_drop = getUpAxisDirections()[m_upAxis] * downVelocity;
m_targetPosition -= (step_drop + gravity_drop);*/

btScalar downVelocity = (m_verticalVelocity<0.f?-m_verticalVelocity:0.f) * dt;
if(downVelocity > 0.0 && downVelocity < m_stepHeight
&& (m_wasOnGround || !m_wasJumping))
{
downVelocity = m_stepHeight;
}

btVector3 step_drop = getUpAxisDirections()[m_upAxis] * (m_currentStepOffset + downVelocity);
m_targetPosition -= step_drop;

start.setIdentity ();
end.setIdentity ();

start.setOrigin (m_currentPosition);
end.setOrigin (m_targetPosition);

btKinematicClosestNotMeConvexResultCallback callback (m_ghostObject, getUpAxisDirections()[m_upAxis], m_maxSlopeCosine);
callback.m_collisionFilterGroup = getGhostObject()->getBroadphaseHandle()->m_collisionFilterGroup;
callback.m_collisionFilterMask = getGhostObject()->getBroadphaseHandle()->m_collisionFilterMask;
if (m_useGhostObjectSweepTest)
{
m_ghostObject->convexSweepTest (m_convexShape, start, end, callback, collisionWorld->getDispatchInfo().m_allowedCcdPenetration);
} else
{
collisionWorld->convexSweepTest (m_convexShape, start, end, callback, collisionWorld->getDispatchInfo().m_allowedCcdPenetration);
}

if (callback.hasHit())
{
// we dropped a fraction of the height -> hit floor
m_currentPosition.setInterpolate3 (m_currentPosition, m_targetPosition, callback.m_closestHitFraction);
m_verticalVelocity = 0.0;
m_verticalOffset = 0.0;
m_wasJumping = false;
} else {
// we dropped the full height
m_currentPosition = m_targetPosition;
}
}



void BulletKinematicCharacterController::setWalkDirection
(
const btVector3& walkDirection
)
{
m_useWalkDirection = true;
m_walkDirection = walkDirection;
m_normalizedDirection = getNormalizedVector(m_walkDirection);
}



void BulletKinematicCharacterController::setVelocityForTimeInterval
(
const btVector3& velocity,
btScalar timeInterval
)
{
// printf("setVelocity!\n");
// printf(" interval: %f\n", timeInterval);
// printf(" velocity: (%f, %f, %f)\n",
// velocity.x(), velocity.y(), velocity.z());

m_useWalkDirection = false;
m_walkDirection = velocity;
m_normalizedDirection = getNormalizedVector(m_walkDirection);
m_velocityTimeInterval = timeInterval;
}



void BulletKinematicCharacterController::reset ()
{
}

void BulletKinematicCharacterController::warp (const btVector3& origin)
{
btTransform xform;
xform.setIdentity();
xform.setOrigin (origin);
m_ghostObject->setWorldTransform (xform);
}


void BulletKinematicCharacterController::preStep ( btCollisionWorld* collisionWorld)
{
int numPenetrationLoops = 0;
m_touchingContact = false;
while (recoverFromPenetration (collisionWorld))
{
numPenetrationLoops++;
m_touchingContact = true;
if (numPenetrationLoops > 4)
{
//printf("character could not recover from penetration = %d\n", numPenetrationLoops);
break;
}
}

m_currentPosition = m_ghostObject->getWorldTransform().getOrigin();
m_targetPosition = m_currentPosition;
// printf("m_targetPosition=%f,%f,%f\n",m_targetPosition[0],m_targetPosition[1],m_targetPosition[2]);

}

#include <stdio.h>

void BulletKinematicCharacterController::playerStep ( btCollisionWorld* collisionWorld, btScalar dt)
{
// printf("playerStep(): ");
// printf(" dt = %f", dt);

// quick check...
if (!m_useWalkDirection && m_velocityTimeInterval <= 0.0) {
// printf("\n");
return; // no motion
}

m_wasOnGround = onGround();

// Update fall velocity.
m_verticalVelocity -= m_gravity * dt;
if(m_verticalVelocity > 0.0 && m_verticalVelocity > m_jumpSpeed)
{
m_verticalVelocity = m_jumpSpeed;
}
if(m_verticalVelocity < 0.0 && btFabs(m_verticalVelocity) > btFabs(m_fallSpeed))
{
m_verticalVelocity = -btFabs(m_fallSpeed);
}
m_verticalOffset = m_verticalVelocity * dt;


btTransform xform;
xform = m_ghostObject->getWorldTransform ();

// printf("walkDirection(%f,%f,%f)\n",walkDirection[0],walkDirection[1],walkDirection[2]);
// printf("walkSpeed=%f\n",walkSpeed);

stepUp (collisionWorld);
if (m_useWalkDirection) {
stepForwardAndStrafe (collisionWorld, m_walkDirection);
} else {
//printf(" time: %f", m_velocityTimeInterval);
// still have some time left for moving!
btScalar dtMoving =
(dt < m_velocityTimeInterval) ? dt : m_velocityTimeInterval;
m_velocityTimeInterval -= dt;

// how far will we move while we are moving?
btVector3 move = m_walkDirection * dtMoving;

//printf(" dtMoving: %f", dtMoving);

// okay, step
stepForwardAndStrafe(collisionWorld, move);
}
stepDown (collisionWorld, dt);

// printf("\n");

xform.setOrigin (m_currentPosition);
m_ghostObject->setWorldTransform (xform);
}

void BulletKinematicCharacterController::setFallSpeed (btScalar fallSpeed)
{
m_fallSpeed = fallSpeed;
}

void BulletKinematicCharacterController::setJumpSpeed (btScalar jumpSpeed)
{
m_jumpSpeed = jumpSpeed;
}

void BulletKinematicCharacterController::setMaxJumpHeight (btScalar maxJumpHeight)
{
m_maxJumpHeight = maxJumpHeight;
}

bool BulletKinematicCharacterController::canJump () const
{
return onGround();
}

void BulletKinematicCharacterController::jump ()
{
if (!canJump())
return;

m_verticalVelocity = m_jumpSpeed;
m_wasJumping = true;

#if 0
currently no jumping.
btTransform xform;
m_rigidBody->getMotionState()->getWorldTransform (xform);
btVector3 up = xform.getBasis()[1];
up.normalize ();
btScalar magnitude = (btScalar(1.0)/m_rigidBody->getInvMass()) * btScalar(8.0);
m_rigidBody->applyCentralImpulse (up * magnitude);
#endif
}

void BulletKinematicCharacterController::setGravity(btScalar gravity)
{
m_gravity = gravity;
}

btScalar BulletKinematicCharacterController::getGravity() const
{
return m_gravity;
}

void BulletKinematicCharacterController::setMaxSlope(btScalar slopeRadians)
{
m_maxSlopeRadians = slopeRadians;
m_maxSlopeCosine = btCos(slopeRadians);
}

btScalar BulletKinematicCharacterController::getMaxSlope() const
{
return m_maxSlopeRadians;
}

bool BulletKinematicCharacterController::onGround () const
{
return m_verticalVelocity == 0.0 && m_verticalOffset == 0.0;
}


btVector3* BulletKinematicCharacterController::getUpAxisDirections()
{
static btVector3 sUpAxisDirection[3] = { btVector3(1.0f, 0.0f, 0.0f), btVector3(0.0f, 1.0f, 0.0f), btVector3(0.0f, 0.0f, 1.0f) };
return sUpAxisDirection;
}

void BulletKinematicCharacterController::debugDraw(btIDebugDraw* debugDrawer)
{
}


#endif // HAVE_PHYS_USE_BULLET
#endif // 0

} /* namespace phys */



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