hl2_src-leak-2017/src/public/jigglebones.cpp

//========= Copyright Valve Corporation, All rights reserved. ============//
//
// Purpose: 
//
// $NoKeywords: $
//===========================================================================//

#include "tier1/convar.h"
#include "jigglebones.h"

#ifdef CLIENT_DLL
#include "engine/ivdebugoverlay.h"
#include "cdll_client_int.h"
#endif // CLIENT_DLL

// memdbgon must be the last include file in a .cpp file!!!
#include "tier0/memdbgon.h"

#ifdef CLIENT_DLL
//-----------------------------------------------------------------------------
ConVar cl_jiggle_bone_debug( "cl_jiggle_bone_debug", "0", FCVAR_CHEAT, "Display physics-based 'jiggle bone' debugging information" );
ConVar cl_jiggle_bone_debug_yaw_constraints( "cl_jiggle_bone_debug_yaw_constraints", "0", FCVAR_CHEAT, "Display physics-based 'jiggle bone' debugging information" );
ConVar cl_jiggle_bone_debug_pitch_constraints( "cl_jiggle_bone_debug_pitch_constraints", "0", FCVAR_CHEAT, "Display physics-based 'jiggle bone' debugging information" );
#endif // CLIENT_DLL

ConVar cl_jiggle_bone_framerate_cutoff( "cl_jiggle_bone_framerate_cutoff", "20", 0, "Skip jiggle bone simulation if framerate drops below this value (frames/second)" );


//-----------------------------------------------------------------------------
JiggleData * CJiggleBones::GetJiggleData( int bone, float currenttime, const Vector &initBasePos, const Vector &initTipPos )
{
	FOR_EACH_LL( m_jiggleBoneState, it )
	{
		if ( m_jiggleBoneState[it].bone == bone )
		{
			return &m_jiggleBoneState[it];
		}
	}

	JiggleData data;
	data.Init( bone, currenttime, initBasePos, initTipPos );

	// Start out using jiggle bones for at least 16 frames.
	data.useGoalMatrixCount = 0;
	data.useJiggleBoneCount = 16;

	int idx = m_jiggleBoneState.AddToHead( data );
	if ( idx == m_jiggleBoneState.InvalidIndex() )
		return NULL;

	return &m_jiggleBoneState[idx];
}


//-----------------------------------------------------------------------------
/**
 * Do spring physics calculations and update "jiggle bone" matrix
 * (Michael Booth, Turtle Rock Studios)
 */
void CJiggleBones::BuildJiggleTransformations( int boneIndex, float currenttime, const mstudiojigglebone_t *jiggleInfo, const matrix3x4_t &goalMX, matrix3x4_t &boneMX )
{
	Vector goalBasePosition;
	MatrixPosition( goalMX, goalBasePosition );

	Vector goalForward, goalUp, goalLeft;
	MatrixGetColumn( goalMX, 0, goalLeft );
	MatrixGetColumn( goalMX, 1, goalUp );
	MatrixGetColumn( goalMX, 2, goalForward );

	// compute goal tip position
	Vector goalTip = goalBasePosition + jiggleInfo->length * goalForward;

	JiggleData *data = GetJiggleData( boneIndex, currenttime, goalBasePosition, goalTip );
	if ( !data )
	{
		return;
	}

	// if frames have been skipped since our last update, we were likely
	// disabled and re-enabled, so re-init
#if defined(CLIENT_DLL) || defined(GAME_DLL)
	float timeTolerance = 1.2f * gpGlobals->frametime;
#else
	float timeTolerance = 0.5f;
#endif

	if ( currenttime - data->lastUpdate > timeTolerance )
	{
		data->Init( boneIndex, currenttime, goalBasePosition, goalTip );
	}

	if ( data->lastLeft.IsZero() )
	{
		data->lastLeft = goalLeft;
	}

	// limit maximum deltaT to avoid simulation blowups
	// if framerate is too low, skip jigglebones altogether, since movement will be too
	// large between frames to simulate with a simple Euler integration
	float deltaT = currenttime - data->lastUpdate;

	const float thousandHZ = 0.001f;
	bool bMaxDeltaT = deltaT < thousandHZ;
	bool bUseGoalMatrix = cl_jiggle_bone_framerate_cutoff.GetFloat() <= 0.0f || deltaT > ( 1.0f / cl_jiggle_bone_framerate_cutoff.GetFloat() );

	if ( bUseGoalMatrix )
	{
		// We hit the jiggle bone framerate cutoff. Reset the useGoalMatrixCount so we
		//  use the goal matrix at least 32 frames and don't flash back and forth.
		data->useGoalMatrixCount = 32;
	}
	else if ( data->useGoalMatrixCount > 0 )
	{
		// Below the cutoff, but still need to use the goal matrix a few more times.
		bUseGoalMatrix = true;
		data->useGoalMatrixCount--;
	}
	else
	{
		// Use real jiggle bones. Woot!
		data->useJiggleBoneCount = 32;
	}

	if ( data->useJiggleBoneCount > 0 )
	{
		// Make sure we draw at least runs of 32 frames with real jiggle bones.
		data->useJiggleBoneCount--;
		data->useGoalMatrixCount = 0;
		bUseGoalMatrix = false;
	}

	if ( bMaxDeltaT )
	{
		deltaT = thousandHZ;
	}
	else if ( bUseGoalMatrix )
	{
		// disable jigglebone - just use goal matrix
		boneMX = goalMX;
		return;
	}

	// we want lastUpdate here, so if jigglebones were skipped they get reinitialized if they turn back on
	data->lastUpdate = currenttime;

	//
	// Bone tip flex
	//
	if ( jiggleInfo->flags & ( JIGGLE_IS_FLEXIBLE | JIGGLE_IS_RIGID ) )
	{
		// apply gravity in global space
		data->tipAccel.z -= jiggleInfo->tipMass;

		if ( jiggleInfo->flags & JIGGLE_IS_FLEXIBLE )
		{
			// decompose into local coordinates
			Vector error = goalTip - data->tipPos;

			Vector localError;
			localError.x = DotProduct( goalLeft, error );
			localError.y = DotProduct( goalUp, error );
			localError.z = DotProduct( goalForward, error );

			Vector localVel;
			localVel.x = DotProduct( goalLeft, data->tipVel );
			localVel.y = DotProduct( goalUp, data->tipVel );

			// yaw spring
			float yawAccel = jiggleInfo->yawStiffness * localError.x - jiggleInfo->yawDamping * localVel.x;

			// pitch spring
			float pitchAccel = jiggleInfo->pitchStiffness * localError.y - jiggleInfo->pitchDamping * localVel.y;

			if ( jiggleInfo->flags & JIGGLE_HAS_LENGTH_CONSTRAINT )
			{
				// drive tip towards goal tip position	
				data->tipAccel += yawAccel * goalLeft + pitchAccel * goalUp;
			}
			else
			{
				// allow flex along length of spring
				localVel.z = DotProduct( goalForward, data->tipVel );

				// along spring
				float alongAccel = jiggleInfo->alongStiffness * localError.z - jiggleInfo->alongDamping * localVel.z;

				// drive tip towards goal tip position	
				data->tipAccel += yawAccel * goalLeft + pitchAccel * goalUp + alongAccel * goalForward;
			}
		}


		// simple euler integration		
		data->tipVel += data->tipAccel * deltaT;
		data->tipPos += data->tipVel * deltaT;

		// clear this timestep's accumulated accelerations
		data->tipAccel = vec3_origin;		

		//
		// Apply optional constraints
		//
		if ( jiggleInfo->flags & ( JIGGLE_HAS_YAW_CONSTRAINT | JIGGLE_HAS_PITCH_CONSTRAINT ) )
		{
			// find components of spring vector in local coordinate system
			Vector along = data->tipPos - goalBasePosition;
			Vector localAlong;
			localAlong.x = DotProduct( goalLeft, along );
			localAlong.y = DotProduct( goalUp, along );
			localAlong.z = DotProduct( goalForward, along );

			Vector localVel;
			localVel.x = DotProduct( goalLeft, data->tipVel );
			localVel.y = DotProduct( goalUp, data->tipVel );
			localVel.z = DotProduct( goalForward, data->tipVel );

			if ( jiggleInfo->flags & JIGGLE_HAS_YAW_CONSTRAINT )
			{
				// enforce yaw constraints in local XZ plane
				float yawError = atan2( localAlong.x, localAlong.z );

				bool isAtLimit = false;
				float yaw = 0.0f;

				if ( yawError < jiggleInfo->minYaw )
				{
					// at angular limit
					isAtLimit = true;
					yaw = jiggleInfo->minYaw;
				}
				else if ( yawError > jiggleInfo->maxYaw )
				{
					// at angular limit
					isAtLimit = true;
					yaw = jiggleInfo->maxYaw;
				}

				if ( isAtLimit )
				{
					float sy, cy;
					SinCos( yaw, &sy, &cy );

					// yaw matrix
					matrix3x4_t yawMatrix;

					yawMatrix[0][0] = cy;
					yawMatrix[1][0] = 0;
					yawMatrix[2][0] = -sy;

					yawMatrix[0][1] = 0;
					yawMatrix[1][1] = 1.0f;
					yawMatrix[2][1] = 0;

					yawMatrix[0][2] = sy;
					yawMatrix[1][2] = 0;
					yawMatrix[2][2] = cy;

					yawMatrix[0][3] = 0;
					yawMatrix[1][3] = 0;
					yawMatrix[2][3] = 0;

					// global coordinates of limit
					matrix3x4_t limitMatrix;					
					ConcatTransforms( goalMX, yawMatrix, limitMatrix );

					Vector limitLeft( limitMatrix.m_flMatVal[0][0], 
									  limitMatrix.m_flMatVal[1][0],
									  limitMatrix.m_flMatVal[2][0] );

					Vector limitUp( limitMatrix.m_flMatVal[0][1], 
									limitMatrix.m_flMatVal[1][1],
									limitMatrix.m_flMatVal[2][1] );

					Vector limitForward( limitMatrix.m_flMatVal[0][2], 
										 limitMatrix.m_flMatVal[1][2],
										 limitMatrix.m_flMatVal[2][2] );

#ifdef CLIENT_DLL
					if ( cl_jiggle_bone_debug_yaw_constraints.GetBool() )
					{
						float dT = 0.01f;
						const float axisSize = 10.0f;
						if ( debugoverlay )
						{
							debugoverlay->AddLineOverlay( goalBasePosition, goalBasePosition + axisSize * limitLeft, 0, 255, 255, true, dT );
							debugoverlay->AddLineOverlay( goalBasePosition, goalBasePosition + axisSize * limitUp, 255, 255, 0, true, dT );
							debugoverlay->AddLineOverlay( goalBasePosition, goalBasePosition + axisSize * limitForward, 255, 0, 255, true, dT );
						}
					}
#endif // CLIENT_DLL

					Vector limitAlong( DotProduct( limitLeft, along ), 
									   DotProduct( limitUp, along ),
									   DotProduct( limitForward, along ) );

					// clip to limit plane
					data->tipPos = goalBasePosition + limitAlong.y * limitUp + limitAlong.z * limitForward;

					// removed friction and velocity clipping against constraint - was causing simulation blowups (MSB 12/9/2010)
					data->tipVel.Zero();

					// update along vectors for use by pitch constraint
					along = data->tipPos - goalBasePosition;
					localAlong.x = DotProduct( goalLeft, along );
					localAlong.y = DotProduct( goalUp, along );
					localAlong.z = DotProduct( goalForward, along );

					localVel.x = DotProduct( goalLeft, data->tipVel );
					localVel.y = DotProduct( goalUp, data->tipVel );
					localVel.z = DotProduct( goalForward, data->tipVel );
				}
			}


			if ( jiggleInfo->flags & JIGGLE_HAS_PITCH_CONSTRAINT )
			{
				// enforce pitch constraints in local YZ plane
				float pitchError = atan2( localAlong.y, localAlong.z );

				bool isAtLimit = false;
				float pitch = 0.0f;

				if ( pitchError < jiggleInfo->minPitch )
				{
					// at angular limit
					isAtLimit = true;
					pitch = jiggleInfo->minPitch;
				}
				else if ( pitchError > jiggleInfo->maxPitch )
				{
					// at angular limit
					isAtLimit = true;
					pitch = jiggleInfo->maxPitch;
				}

				if ( isAtLimit )
				{
					float sp, cp;
					SinCos( pitch, &sp, &cp );

					// pitch matrix
					matrix3x4_t pitchMatrix;

					pitchMatrix[0][0] = 1.0f;
					pitchMatrix[1][0] = 0;
					pitchMatrix[2][0] = 0;

					pitchMatrix[0][1] = 0;
					pitchMatrix[1][1] = cp;
					pitchMatrix[2][1] = -sp;

					pitchMatrix[0][2] = 0;
					pitchMatrix[1][2] = sp;
					pitchMatrix[2][2] = cp;

					pitchMatrix[0][3] = 0;
					pitchMatrix[1][3] = 0;
					pitchMatrix[2][3] = 0;

					// global coordinates of limit
					matrix3x4_t limitMatrix;					
					ConcatTransforms( goalMX, pitchMatrix, limitMatrix );

					Vector limitLeft( limitMatrix.m_flMatVal[0][0], 
									  limitMatrix.m_flMatVal[1][0],
									  limitMatrix.m_flMatVal[2][0] );

					Vector limitUp( limitMatrix.m_flMatVal[0][1], 
									limitMatrix.m_flMatVal[1][1],
									limitMatrix.m_flMatVal[2][1] );

					Vector limitForward( limitMatrix.m_flMatVal[0][2], 
										 limitMatrix.m_flMatVal[1][2],
										 limitMatrix.m_flMatVal[2][2] );

#ifdef CLIENT_DLL
					if (cl_jiggle_bone_debug_pitch_constraints.GetBool())
					{
						float dT = 0.01f;
						const float axisSize = 10.0f;
						if ( debugoverlay )
						{
							debugoverlay->AddLineOverlay( goalBasePosition, goalBasePosition + axisSize * limitLeft, 0, 255, 255, true, dT );
							debugoverlay->AddLineOverlay( goalBasePosition, goalBasePosition + axisSize * limitUp, 255, 255, 0, true, dT );
							debugoverlay->AddLineOverlay( goalBasePosition, goalBasePosition + axisSize * limitForward, 255, 0, 255, true, dT );
						}
					}
#endif // CLIENT_DLL

					Vector limitAlong( DotProduct( limitLeft, along ), 
									   DotProduct( limitUp, along ),
									   DotProduct( limitForward, along ) );

					// clip to limit plane
					data->tipPos = goalBasePosition + limitAlong.x * limitLeft + limitAlong.z * limitForward;

					// removed friction and velocity clipping against constraint - was causing simulation blowups (MSB 12/9/2010)
					data->tipVel.Zero();
				}
			}
		}

		// needed for matrix assembly below
		Vector forward = data->tipPos - goalBasePosition;
		forward.NormalizeInPlace();

		if ( jiggleInfo->flags & JIGGLE_HAS_ANGLE_CONSTRAINT )
		{
			// enforce max angular error
			Vector error = goalTip - data->tipPos;
			float dot = DotProduct( forward, goalForward );
			float angleBetween = acos( dot );
			if ( dot < 0.0f )
			{
				angleBetween = 2.0f * M_PI - angleBetween;
			}

			if ( angleBetween > jiggleInfo->angleLimit )
			{
				// at angular limit
				float maxBetween = jiggleInfo->length * sin( jiggleInfo->angleLimit );

				Vector delta = goalTip - data->tipPos;
				delta.NormalizeInPlace();

				data->tipPos = goalTip - maxBetween * delta;

				forward = data->tipPos - goalBasePosition;
				forward.NormalizeInPlace();
			}
		}

		if ( jiggleInfo->flags & JIGGLE_HAS_LENGTH_CONSTRAINT )
		{
			// enforce spring length
			data->tipPos = goalBasePosition + jiggleInfo->length * forward;

			// zero velocity along forward bone axis
			data->tipVel -= DotProduct( data->tipVel, forward ) * forward;
		}

		//
		// Build bone matrix to align along current tip direction
		//
		Vector left = CrossProduct( goalUp, forward );
		left.NormalizeInPlace();

		if ( DotProduct( left, data->lastLeft ) < 0.0f )
		{
			// The bone has rotated so far its on the other side of the up vector
			// resulting in the cross product result flipping 180 degrees around the up
			// vector.  Flip it back.
			left = -left;
		}
		data->lastLeft = left;

#ifdef CLIENT_DLL
		if ( cl_jiggle_bone_debug.GetBool() )
		{
			if ( debugoverlay )
			{
				debugoverlay->AddLineOverlay( goalBasePosition, goalBasePosition + 10.0f * data->lastLeft, 255, 0, 255, true, 0.01f );
			}
		}
#endif

		Vector up = CrossProduct( forward, left );

		boneMX[0][0] = left.x;
		boneMX[1][0] = left.y;
		boneMX[2][0] = left.z;
		boneMX[0][1] = up.x;
		boneMX[1][1] = up.y;
		boneMX[2][1] = up.z;
		boneMX[0][2] = forward.x;
		boneMX[1][2] = forward.y;
		boneMX[2][2] = forward.z;

		boneMX[0][3] = goalBasePosition.x;
		boneMX[1][3] = goalBasePosition.y;
		boneMX[2][3] = goalBasePosition.z;
	}


	//
	// Bone base flex
	//
	if ( jiggleInfo->flags & JIGGLE_HAS_BASE_SPRING )
	{
		// gravity
		data->baseAccel.z -= jiggleInfo->baseMass;

		// simple spring
		Vector error = goalBasePosition - data->basePos;
		data->baseAccel += jiggleInfo->baseStiffness * error - jiggleInfo->baseDamping * data->baseVel;

		data->baseVel += data->baseAccel * deltaT;
		data->basePos += data->baseVel * deltaT;

		// clear this timestep's accumulated accelerations
		data->baseAccel = vec3_origin;		

		// constrain to limits
		error = data->basePos - goalBasePosition;
		Vector localError;
		localError.x = DotProduct( goalLeft, error );
		localError.y = DotProduct( goalUp, error );
		localError.z = DotProduct( goalForward, error );

		Vector localVel;
		localVel.x = DotProduct( goalLeft, data->baseVel );
		localVel.y = DotProduct( goalUp, data->baseVel );
		localVel.z = DotProduct( goalForward, data->baseVel );

		// horizontal constraint
		if ( localError.x < jiggleInfo->baseMinLeft )
		{
			localError.x = jiggleInfo->baseMinLeft;

			// friction
			data->baseAccel -= jiggleInfo->baseLeftFriction * (localVel.y * goalUp + localVel.z * goalForward);
		}
		else if ( localError.x > jiggleInfo->baseMaxLeft )
		{
			localError.x = jiggleInfo->baseMaxLeft;

			// friction
			data->baseAccel -= jiggleInfo->baseLeftFriction * (localVel.y * goalUp + localVel.z * goalForward);
		}

		if ( localError.y < jiggleInfo->baseMinUp )
		{
			localError.y = jiggleInfo->baseMinUp;

			// friction
			data->baseAccel -= jiggleInfo->baseUpFriction * (localVel.x * goalLeft + localVel.z * goalForward);
		}
		else if ( localError.y > jiggleInfo->baseMaxUp )
		{
			localError.y = jiggleInfo->baseMaxUp;

			// friction
			data->baseAccel -= jiggleInfo->baseUpFriction * (localVel.x * goalLeft + localVel.z * goalForward);
		}

		if ( localError.z < jiggleInfo->baseMinForward )
		{
			localError.z = jiggleInfo->baseMinForward;

			// friction
			data->baseAccel -= jiggleInfo->baseForwardFriction * (localVel.x * goalLeft + localVel.y * goalUp);
		}
		else if ( localError.z > jiggleInfo->baseMaxForward )
		{
			localError.z = jiggleInfo->baseMaxForward;

			// friction
			data->baseAccel -= jiggleInfo->baseForwardFriction * (localVel.x * goalLeft + localVel.y * goalUp);
		}

		data->basePos = goalBasePosition + localError.x * goalLeft + localError.y * goalUp + localError.z * goalForward;


		// fix up velocity
		data->baseVel = (data->basePos - data->baseLastPos) / deltaT;
		data->baseLastPos = data->basePos;


		if ( !( jiggleInfo->flags & ( JIGGLE_IS_FLEXIBLE | JIGGLE_IS_RIGID ) ) )
		{
			// no tip flex - use bone's goal orientation
			boneMX = goalMX;							
		}

		// update bone position
		MatrixSetColumn( data->basePos, 3, boneMX );
	}
	else if ( jiggleInfo->flags & JIGGLE_IS_BOING )
	{
		// estimate velocity
		Vector vel = goalBasePosition - data->lastBoingPos;

#ifdef CLIENT_DLL
		if ( cl_jiggle_bone_debug.GetBool() )
		{
			if ( debugoverlay )
			{
				debugoverlay->AddLineOverlay( data->lastBoingPos, goalBasePosition, 0, 128, ( gpGlobals->framecount & 0x1 ) ? 0 : 200, true, 999.9f );
			}
		}
#endif

		data->lastBoingPos = goalBasePosition;

		float speed = vel.NormalizeInPlace();
		if ( speed < 0.00001f )
		{
			vel = Vector( 0, 0, 1.0f );
			speed = 0.0f;
		}
		else
		{
			speed /= deltaT;
		}

		data->boingTime += deltaT;

		// if velocity changed a lot, we impacted and should *boing*
		const float minSpeed = 5.0f; // 15.0f;
		const float minReBoingTime = 0.5f;
		if ( ( speed > minSpeed || data->boingSpeed > minSpeed ) && data->boingTime > minReBoingTime )
		{
			if ( fabs( data->boingSpeed - speed ) > jiggleInfo->boingImpactSpeed || DotProduct( vel, data->boingVelDir ) < jiggleInfo->boingImpactAngle )
			{
				data->boingTime = 0.0f;
				data->boingDir = -vel;

#ifdef CLIENT_DLL
				if ( cl_jiggle_bone_debug.GetBool() )
				{
					if ( debugoverlay )
					{
						debugoverlay->AddLineOverlay( goalBasePosition, goalBasePosition + 5.0f * data->boingDir, 255, 255, 0, true, 999.9f );
						debugoverlay->AddLineOverlay( goalBasePosition, goalBasePosition + Vector( 0.1, 0, 0 ), 128, 128, 0, true, 999.9f );
						debugoverlay->AddLineOverlay( goalBasePosition, goalBasePosition + Vector( 0, 0.1, 0 ), 128, 128, 0, true, 999.9f );
						debugoverlay->AddLineOverlay( goalBasePosition, goalBasePosition + Vector( 0, 0, 0.1 ), 128, 128, 0, true, 999.9f );
					}
				}
#endif
			}
		}

		data->boingVelDir = vel;
		data->boingSpeed = speed;

		float damping = 1.0f - ( jiggleInfo->boingDampingRate * data->boingTime );
		if ( damping < 0.01f )
		{
			// boing has entirely damped out
			boneMX = goalMX;
		}
		else
		{
			damping *= damping;
			damping *= damping;

			float flex = jiggleInfo->boingAmplitude * cos( jiggleInfo->boingFrequency * data->boingTime ) * damping;

 			float squash = 1.0f + flex;
 			float stretch = 1.0f - flex;


			boneMX[0][0] = goalLeft.x;
			boneMX[1][0] = goalLeft.y;
			boneMX[2][0] = goalLeft.z;

			boneMX[0][1] = goalUp.x;
			boneMX[1][1] = goalUp.y;
			boneMX[2][1] = goalUp.z;

			boneMX[0][2] = goalForward.x;
			boneMX[1][2] = goalForward.y;
			boneMX[2][2] = goalForward.z;

			boneMX[0][3] = 0.0f;
			boneMX[1][3] = 0.0f;
			boneMX[2][3] = 0.0f;


			// build transform into "boing space", where Z is along primary boing axis
			Vector boingSide;
			if ( fabs( data->boingDir.x ) < 0.9f )
			{
				boingSide = CrossProduct( data->boingDir, Vector( 1.0f, 0, 0 ) );
			}
			else
			{
				boingSide = CrossProduct( data->boingDir, Vector( 0, 0, 1.0f ) );
			}
			boingSide.NormalizeInPlace();

			Vector boingOtherSide = CrossProduct( data->boingDir, boingSide );

			matrix3x4_t xfrmToBoingCoordsMX;

			xfrmToBoingCoordsMX[0][0] = boingSide.x;
			xfrmToBoingCoordsMX[0][1] = boingSide.y;
			xfrmToBoingCoordsMX[0][2] = boingSide.z;

			xfrmToBoingCoordsMX[1][0] = boingOtherSide.x;
			xfrmToBoingCoordsMX[1][1] = boingOtherSide.y;
			xfrmToBoingCoordsMX[1][2] = boingOtherSide.z;

			xfrmToBoingCoordsMX[2][0] = data->boingDir.x;
			xfrmToBoingCoordsMX[2][1] = data->boingDir.y;
			xfrmToBoingCoordsMX[2][2] = data->boingDir.z;

			xfrmToBoingCoordsMX[0][3] = 0.0f;
			xfrmToBoingCoordsMX[1][3] = 0.0f;
			xfrmToBoingCoordsMX[2][3] = 0.0f;

			// build squash and stretch transform in "boing space"
			matrix3x4_t boingMX;

			boingMX[0][0] = squash;
			boingMX[1][0] = 0.0f;
			boingMX[2][0] = 0.0f;

			boingMX[0][1] = 0.0f;
			boingMX[1][1] = squash;
			boingMX[2][1] = 0.0f;

			boingMX[0][2] = 0.0f;
			boingMX[1][2] = 0.0f;
			boingMX[2][2] = stretch;

			boingMX[0][3] = 0.0f;
			boingMX[1][3] = 0.0f;
			boingMX[2][3] = 0.0f;

			// transform back from boing space (inverse is transpose since orthogonal)
			matrix3x4_t xfrmFromBoingCoordsMX;
			xfrmFromBoingCoordsMX[0][0] = xfrmToBoingCoordsMX[0][0];
			xfrmFromBoingCoordsMX[1][0] = xfrmToBoingCoordsMX[0][1];
			xfrmFromBoingCoordsMX[2][0] = xfrmToBoingCoordsMX[0][2];

			xfrmFromBoingCoordsMX[0][1] = xfrmToBoingCoordsMX[1][0];
			xfrmFromBoingCoordsMX[1][1] = xfrmToBoingCoordsMX[1][1];
			xfrmFromBoingCoordsMX[2][1] = xfrmToBoingCoordsMX[1][2];

			xfrmFromBoingCoordsMX[0][2] = xfrmToBoingCoordsMX[2][0];
			xfrmFromBoingCoordsMX[1][2] = xfrmToBoingCoordsMX[2][1];
			xfrmFromBoingCoordsMX[2][2] = xfrmToBoingCoordsMX[2][2];

			xfrmFromBoingCoordsMX[0][3] = 0.0f;
			xfrmFromBoingCoordsMX[1][3] = 0.0f;
			xfrmFromBoingCoordsMX[2][3] = 0.0f;

			// put it all together
			matrix3x4_t xfrmMX;
			MatrixMultiply( xfrmToBoingCoordsMX, boingMX, xfrmMX );
			MatrixMultiply( xfrmMX, xfrmFromBoingCoordsMX, xfrmMX );
			MatrixMultiply( boneMX, xfrmMX, boneMX );

#ifdef CLIENT_DLL
			if ( cl_jiggle_bone_debug.GetBool() )
			{
				float dT = 0.01f;
				if ( debugoverlay )
				{
					debugoverlay->AddLineOverlay( goalBasePosition, goalBasePosition + 50.0f * data->boingDir, 255, 255, 0, true, dT );
					debugoverlay->AddLineOverlay( goalBasePosition, goalBasePosition + 50.0f * boingSide, 255, 0, 255, true, dT );
					debugoverlay->AddLineOverlay( goalBasePosition, goalBasePosition + 50.0f * boingOtherSide, 0, 255, 255, true, dT );
				}
			}
#endif

			boneMX[0][3] = goalBasePosition.x;
			boneMX[1][3] = goalBasePosition.y;
			boneMX[2][3] = goalBasePosition.z;
		}
	}
	else if ( !( jiggleInfo->flags & ( JIGGLE_IS_FLEXIBLE | JIGGLE_IS_RIGID ) ) )
	{
		// no flex at all - just use goal matrix
		boneMX = goalMX;
	}

#ifdef CLIENT_DLL
	// debug display for client only so server doesn't try to also draw it
	if ( cl_jiggle_bone_debug.GetBool() )
	{
		float dT = 0.01f;
		const float axisSize = 5.0f;
		if ( debugoverlay )
		{
			debugoverlay->AddLineOverlay( goalBasePosition, goalBasePosition + axisSize * goalLeft, 255, 0, 0, true, dT );
			debugoverlay->AddLineOverlay( goalBasePosition, goalBasePosition + axisSize * goalUp, 0, 255, 0, true, dT );
			debugoverlay->AddLineOverlay( goalBasePosition, goalBasePosition + axisSize * goalForward, 0, 0, 255, true, dT );
		}

		if ( cl_jiggle_bone_debug.GetInt() > 1 )
		{
			DevMsg( "Jiggle bone #%d, basePos( %3.2f, %3.2f, %3.2f ), tipPos( %3.2f, %3.2f, %3.2f ), left( %3.2f, %3.2f, %3.2f ), up( %3.2f, %3.2f, %3.2f ), forward( %3.2f, %3.2f, %3.2f )\n", 
						data->bone,
						goalBasePosition.x, goalBasePosition.y, goalBasePosition.z, 
						data->tipPos.x, data->tipPos.y, data->tipPos.z,
						goalLeft.x, goalLeft.y, goalLeft.z,
						goalUp.x, goalUp.y, goalUp.z,
						goalForward.x, goalForward.y, goalForward.z );
		}

		const float sz = 1.0f;

		if ( jiggleInfo->flags & ( JIGGLE_IS_FLEXIBLE | JIGGLE_IS_RIGID ) )
		{
			if ( debugoverlay )
			{
				debugoverlay->AddLineOverlay( goalBasePosition, 
					data->tipPos, 255, 255, 0, true, dT );

				debugoverlay->AddLineOverlay( data->tipPos + Vector( -sz, 0, 0 ), 
					data->tipPos + Vector( sz, 0, 0 ), 0, 255, 255, true, dT );
				debugoverlay->AddLineOverlay( data->tipPos + Vector( 0, -sz, 0 ), 
					data->tipPos + Vector( 0, sz, 0 ), 0, 255, 255, true, dT );
				debugoverlay->AddLineOverlay( data->tipPos + Vector( 0, 0, -sz ), 
					data->tipPos + Vector( 0, 0, sz ), 0, 255, 255, true, dT );
			}
		}

		if ( jiggleInfo->flags & JIGGLE_HAS_BASE_SPRING )
		{
			if ( debugoverlay )
			{
				debugoverlay->AddLineOverlay( data->basePos + Vector( -sz, 0, 0 ), 
					data->basePos + Vector( sz, 0, 0 ), 255, 0, 255, true, dT );
				debugoverlay->AddLineOverlay( data->basePos + Vector( 0, -sz, 0 ), 
					data->basePos + Vector( 0, sz, 0 ), 255, 0, 255, true, dT );
				debugoverlay->AddLineOverlay( data->basePos + Vector( 0, 0, -sz ), 
					data->basePos + Vector( 0, 0, sz ), 255, 0, 255, true, dT );
			}
		}


		if ( jiggleInfo->flags & JIGGLE_IS_BOING )
		{
			if ( cl_jiggle_bone_debug.GetInt() > 2 )
			{
				DevMsg( "  boingSpeed = %3.2f, boingVelDir( %3.2f, %3.2f, %3.2f )\n", data->boingVelDir.Length() / deltaT, data->boingVelDir.x, data->boingVelDir.y, data->boingVelDir.z );
			}
		}
	}
#endif // CLIENT_DLL
}