Ejemplo n.º 1
0
/**
 * This method will add all the position keys found in the controller to
 * the animation path.
 */
void OSGExp::exportPosKeys(osg::AnimationPath* animationPath, Control* cont){
	if (!cont)
		return;

	int i;
	IKeyControl *ikc = GetKeyControlInterface(cont);
	
	// TCB position
	if (ikc && cont->ClassID() == Class_ID(TCBINTERP_POSITION_CLASS_ID, 0)) {
		int numKeys;
		if (numKeys = ikc->GetNumKeys()) {
			for (i=0; i<numKeys; i++) {
				ITCBPoint3Key key;
				ikc->GetKey(i, &key);
				; // NOT SUPPORTED YET
			}
		}
	}
	// Bezier position
	else if (ikc && cont->ClassID() == Class_ID(HYBRIDINTERP_POSITION_CLASS_ID, 0)){
		int numKeys;
		if(numKeys = ikc->GetNumKeys()){
			for (i=0; i<numKeys; i++) {
				IBezPoint3Key key;
				ikc->GetKey(i, &key);
				; // NOT SUPPORTED YET
			}
		}
	}
	// Linear position
	else if (ikc && cont->ClassID() == Class_ID(LININTERP_POSITION_CLASS_ID, 0)) {
		int numKeys;
		if(numKeys = ikc->GetNumKeys()){
			for (i=0; i<numKeys; i++) {
				ILinPoint3Key key;
				ikc->GetKey(i, &key);
				addControlPos(animationPath, (key.time/(float)TIME_TICKSPERSEC),key.val);
			}
		}
	}
}
Ejemplo n.º 2
0
Interval AnimExportUtil::getKeyFramedRotationRange( INode* node3ds, Interval animRange )
{
	require( node3ds->GetTMController() );

	TimeValue start = animRange.Start();
	TimeValue end = animRange.End();

	// target defines rotation
	if ( node3ds->GetTarget() )
		return Interval( start, start );

	Control* cont = node3ds->GetTMController()->GetRotationController();
	IKeyControl* ikeys = cont ? GetKeyControlInterface( cont ) : 0;
	if ( ikeys )
	{
		ITCBRotKey key1;
		IBezQuatKey key2;
		ILinRotKey key3;
		IKey* keyp = 0;

		if ( cont->ClassID() == Class_ID(TCBINTERP_ROTATION_CLASS_ID, 0) )
			keyp = &key1;
		else if ( cont->ClassID() == Class_ID(HYBRIDINTERP_ROTATION_CLASS_ID, 0) )
			keyp = &key2;
		else if ( cont->ClassID() == Class_ID(LININTERP_ROTATION_CLASS_ID, 0) )
			keyp = &key3;

		if ( keyp )
		{
			if ( 0 == ikeys->GetNumKeys() )
				return Interval( start, start );

			ikeys->GetKey( 0, keyp );
			start = keyp->time;
			ikeys->GetKey( ikeys->GetNumKeys()-1, keyp );
			end = keyp->time;
		}
	}

	return Interval( start, end );
}
Ejemplo n.º 3
0
// ADJUSTROTKEYS
void AdjustRotKeys(INode *node)
{
    Control *controller = node->GetTMController();
    Control *rotControl = controller->GetRotationController();
    IKeyControl *rotKeyCont = GetKeyControlInterface(rotControl);
    int numKeys = rotKeyCont->GetNumKeys();

    for(int i = 0; i < numKeys; i++)
    {
        ITCBKey key;
        rotKeyCont->GetKey(i, &key);

        key.cont = 0;
        rotKeyCont->SetKey(i, &key);

    }
    
}
Ejemplo n.º 4
0
void AsciiExp::DumpScaleKeys(Control* cont, int indentLevel) 
{
	if (!cont)
		return;
	
	int i;
	TSTR indent = GetIndent(indentLevel);
	IKeyControl *ikc = GetKeyControlInterface(cont);
	
	if (ikc && cont->ClassID() == Class_ID(TCBINTERP_SCALE_CLASS_ID, 0))
	{
		int numKeys = ikc->GetNumKeys();
		if (numKeys != 0) {
			_ftprintf(pStream, _T("%s\t\t%s {\n"), indent.data(), ID_CONTROL_SCALE_TCB); 
			for (i=0; i<numKeys; i++) {
				ITCBScaleKey key;
				ikc->GetKey(i, &key);
				_ftprintf(pStream, _T("%s\t\t\t%s %d\t%s"),
					indent.data(),
					ID_TCB_SCALE_KEY,
					key.time,
					Format(key.val));
				_ftprintf(pStream, _T("\t%s\t%s\t%s\t%s\t%s\n"), Format(key.tens), Format(key.cont), Format(key.bias), Format(key.easeIn), Format(key.easeOut));
			}
			_ftprintf(pStream, _T("%s\t\t}\n"), indent.data());
		}
	}
	else if (ikc && cont->ClassID() == Class_ID(HYBRIDINTERP_SCALE_CLASS_ID, 0)) {
		int numKeys = ikc->GetNumKeys();
		if (numKeys != 0) {
			_ftprintf(pStream, _T("%s\t\t%s {\n"), indent.data(), ID_CONTROL_SCALE_BEZIER); 
			for (i=0; i<numKeys; i++) {
				IBezScaleKey key;
				ikc->GetKey(i, &key);
				_ftprintf(pStream, _T("%s\t\t\t%s %d\t%s"),
					indent.data(),
					ID_BEZIER_SCALE_KEY,
					key.time,
					Format(key.val));
				_ftprintf(pStream, _T("\t%s\t%s\t%d\n"), Format(key.intan), Format(key.outtan), key.flags);
			}
			_ftprintf(pStream, _T("%s\t\t}\n"), indent.data());
		}
	}
	else if (ikc && cont->ClassID() == Class_ID(LININTERP_SCALE_CLASS_ID, 0)) {
		int numKeys = ikc->GetNumKeys();
		if (numKeys != 0) {
			_ftprintf(pStream, _T("%s\t\t%s {\n"), indent.data(), ID_CONTROL_SCALE_LINEAR); 
			for (i=0; i<numKeys; i++) {
				ILinScaleKey key;
				ikc->GetKey(i, &key);
				_ftprintf(pStream, _T("%s\t\t\t%s %d\t%s\n"),
					indent.data(),
					ID_SCALE_KEY,
					key.time,
					Format(key.val));
			}
			_ftprintf(pStream, _T("%s\t\t}\n"), indent.data());
		}
	}
}
Ejemplo n.º 5
0
void AsciiExp::DumpRotKeys(Control* cont, int indentLevel) 
{
	if (!cont)
		return;
	
	int i;
	TSTR indent = GetIndent(indentLevel);
	IKeyControl *ikc = GetKeyControlInterface(cont);
	
	if (ikc && cont->ClassID() == Class_ID(TCBINTERP_ROTATION_CLASS_ID, 0)) {
		int numKeys = ikc->GetNumKeys();
		if (numKeys != 0) {
			_ftprintf(pStream, _T("%s\t\t%s {\n"), indent.data(), ID_CONTROL_ROT_TCB); 
			for (i=0; i<numKeys; i++) {
				ITCBRotKey key;
				ikc->GetKey(i, &key);
				_ftprintf(pStream, _T("%s\t\t\t%s %d\t%s"), 
					indent.data(),
					ID_TCB_ROT_KEY,
					key.time,
					Format(key.val));
				_ftprintf(pStream, _T("\t%s\t%s\t%s\t%s\t%s\n"), Format(key.tens), Format(key.cont), Format(key.bias), Format(key.easeIn), Format(key.easeOut));
			}
			_ftprintf(pStream, _T("%s\t\t}\n"), indent.data());
		}
	}
	else if (ikc && cont->ClassID() == Class_ID(HYBRIDINTERP_ROTATION_CLASS_ID, 0))
	{
		int numKeys = ikc->GetNumKeys();
		if (numKeys != 0) {
			_ftprintf(pStream, _T("%s\t\t%s {\n"), indent.data(), ID_CONTROL_ROT_BEZIER); 
			for (i=0; i<numKeys; i++) {
				IBezQuatKey key;
				ikc->GetKey(i, &key);
				_ftprintf(pStream, _T("%s\t\t\t%s %d\t%s\n"), 
					indent.data(),
					 // Quaternions are converted to AngAxis when written to file
					ID_ROT_KEY,
					key.time,
					Format(key.val));
				// There is no intan/outtan for Quat Rotations
			}
			_ftprintf(pStream, _T("%s\t\t}\n"), indent.data());
		}
	}
	else if (ikc && cont->ClassID() == Class_ID(LININTERP_ROTATION_CLASS_ID, 0)) {
		int numKeys = ikc->GetNumKeys();
		if (numKeys != 0) {
			_ftprintf(pStream, _T("%s\t\t%s {\n"), indent.data(), ID_CONTROL_ROT_LINEAR); 
			for (i=0; i<numKeys; i++) {
				ILinRotKey key;
				ikc->GetKey(i, &key);
				_ftprintf(pStream, _T("%s\t\t\t%s %d\t%s\n"),
					indent.data(), 
					 // Quaternions are converted to AngAxis when written to file
					ID_ROT_KEY,
					key.time,
					Format(key.val));
			}
			_ftprintf(pStream, _T("%s\t\t}\n"), indent.data());
		}
	}
}
Ejemplo n.º 6
0
// Output float keys if this is a known float controller that
// supports key operations. Otherwise we will sample the controller 
// once for each frame to get the value.
void AsciiExp::DumpFloatKeys(Control* cont, int indentLevel) 
{
	if (!cont)
		return;
	
	int i;
	TSTR indent = GetIndent(indentLevel);
	IKeyControl *ikc = NULL;

	// If the user wants us to always sample, we will ignore the KeyControlInterface
	if (!GetAlwaysSample())
		ikc = GetKeyControlInterface(cont);
	
	// TCB float
	if (ikc && cont->ClassID() == Class_ID(TCBINTERP_FLOAT_CLASS_ID, 0)) {
		_ftprintf(pStream, _T("%s\t\t%s {\n"), indent.data(), ID_CONTROL_FLOAT_TCB); 
		for (i=0; i<ikc->GetNumKeys(); i++) {
			ITCBFloatKey key;
			ikc->GetKey(i, &key);
			_ftprintf(pStream, _T("%s\t\t\t%s %d\t%s"),
				indent.data(),
				ID_TCB_FLOAT_KEY,
				key.time,
				Format(key.val));
			_ftprintf(pStream, _T("\t%s\t%s\t%s\t%s\t%s\n"), Format(key.tens), Format(key.cont), Format(key.bias), Format(key.easeIn), Format(key.easeOut));
		}
		_ftprintf(pStream, _T("%s\t\t}\n"), indent.data());
	}
	// Bezier float
	else if (ikc && cont->ClassID() == Class_ID(HYBRIDINTERP_FLOAT_CLASS_ID, 0)) {
		_ftprintf(pStream, _T("%s\t\t%s {\n"), indent.data(), ID_CONTROL_FLOAT_BEZIER); 
		for (i=0; i<ikc->GetNumKeys(); i++) {
			IBezFloatKey key;
			ikc->GetKey(i, &key);
			_ftprintf(pStream, _T("%s\t\t\t%s %d\t%s"),
				indent.data(),
				ID_BEZIER_FLOAT_KEY,
				key.time, 
				Format(key.val));
			_ftprintf(pStream, _T("\t%s\t%s\t%d\n"), Format(key.intan), Format(key.outtan), key.flags);
		}
		_ftprintf(pStream, _T("%s\t\t}\n"), indent.data());
	}
	else if (ikc && cont->ClassID() == Class_ID(LININTERP_FLOAT_CLASS_ID, 0)) {
		_ftprintf(pStream, _T("%s\t\t%s {\n"), indent.data(), ID_CONTROL_FLOAT_LINEAR); 
		for (i=0; i<ikc->GetNumKeys(); i++) {
			ILinFloatKey key;
			ikc->GetKey(i, &key);
			_ftprintf(pStream, _T("%s\t\t\t%s %d\t%s\n"),
				indent.data(),
				ID_FLOAT_KEY,
				key.time,
				Format(key.val));
		}
		_ftprintf(pStream, _T("%s\t\t}\n"), indent.data());
	}
	else {
		
		// Unknown controller, no key interface or sample on demand -
		// This might be a procedural controller or something else we
		// don't know about. The last resort is to get the value from the 
		// controller at every n frames.
		
		TSTR name;
		cont->GetClassName(name);
		TSTR className = FixupName(name);
		Interface14 *iface = GetCOREInterface14();
		UINT codepage  = iface-> DefaultTextSaveCodePage(true);
		const char* className_locale = className.ToCP(codepage);
		_ftprintf(pStream, _T("%s\t\t%s \"%hs\" {\n"), indent.data(), ID_CONTROL_FLOAT_SAMPLE,
			className_locale);
		
		// If it is animated at all...
		if (cont->IsAnimated()) {
			// Get the range of the controller animation 
			Interval range; 
			// Get range of full animation
			Interval animRange = ip->GetAnimRange(); 
			TimeValue t = cont->GetTimeRange(TIMERANGE_ALL).Start();
			float value;
			
			// While we are inside the animation... 
			while (animRange.InInterval(t)) {
				// Sample the controller
				range = FOREVER;
				cont->GetValue(t, &value, range);
				
				// Set time to start of controller validity interval 
				t = range.Start();
				
				// Output the sample
				_ftprintf(pStream, _T("%s\t\t\t%s %d\t%s\n"),
					indent.data(),
					ID_FLOAT_KEY,
					t,
					Format(value));
				
				// If the end of the controller validity is beyond the 
				// range of the animation
				if (range.End() > cont->GetTimeRange(TIMERANGE_ALL).End()) {
					break;
				}
				else {
					t = (range.End()/GetTicksPerFrame()+GetKeyFrameStep()) * GetTicksPerFrame();
				}
			}
		}
		_ftprintf(pStream, _T("%s\t\t}\n"), indent.data());
	}
}
Ejemplo n.º 7
0
void XsiExp::DumpScaleKeys( INode * node, int indentLevel) 
{
  Control * cont = node->GetTMController()->GetScaleController();
	IKeyControl * ikc = GetKeyControlInterface(cont);
	INode * parent = node->GetParentNode();
	if (!cont || !parent || (parent && parent->IsRootNode()) || !ikc)
  {
    // no controller or root node
		return;
  }
	int numKeys = ikc->GetNumKeys();
	if (numKeys <= 1)
  {  
    return;
  }
	Object * obj = node->EvalWorldState(0).obj;
  BOOL isBone = obj && obj->ClassID() == Class_ID(BONE_CLASS_ID, 0) ? TRUE : FALSE;

  // anim keys header
  TSTR indent = GetIndent(indentLevel);
	fprintf(pStream,"%s\tSI_AnimationKey {\n", indent.data()); 
	fprintf(pStream,"%s\t\t1;\n", indent.data());     // 1 means scale keys
	fprintf(pStream,"%s\t\t%d;\n", indent.data(), numKeys);

	int t, delta = GetTicksPerFrame();
 	Matrix3 matrix;
  AffineParts ap;
	for (int i = 0; i < numKeys; i++)
  {  
    // get the key's time
	  if (cont->ClassID() == Class_ID(TCBINTERP_SCALE_CLASS_ID, 0))
    {
  	  ITCBRotKey key;
			ikc->GetKey(i, &key);
      t = key.time;
    }
    else if (cont->ClassID() == Class_ID(HYBRIDINTERP_SCALE_CLASS_ID, 0))
	  {
		  IBezQuatKey key;
		  ikc->GetKey(i, &key);
      t = key.time;
    }
	  else if (cont->ClassID() == Class_ID(LININTERP_SCALE_CLASS_ID, 0))
    {
  	  ILinRotKey key;
		  ikc->GetKey(i, &key);
      t = key.time;
    }
    // sample the node's matrix
    matrix = node->GetNodeTM(t) * Inverse(node->GetParentTM(t));
    if (!isBone)
    {
      matrix = matrix * topMatrix;
    }
    decomp_affine(matrix, &ap);

		fprintf(pStream, "%s\t\t%d; 3; %.6f, %.6f, %.6f;;%s\n", 
			indent.data(),
			t / delta,
			ap.k.x, ap.k.z, ap.k.y,
      i == numKeys - 1 ? ";\n" : ",");
	}
  // anim keys close
	fprintf(pStream,"%s\t}\n\n", indent.data());
}
Ejemplo n.º 8
0
void KeyTest() 
{
	int i, numKeys;
	INode *         n;
	Control *       c;
	Quat            newQuat, prevQuat;
	IKeyControl*    ikeys;
	ITCBPoint3Key   tcbPosKey;
	ITCBRotKey      tcbRotKey;
	ITCBScaleKey    tcbScaleKey;
	IBezPoint3Key   bezPosKey;
	IBezQuatKey     bezRotKey;
	IBezScaleKey    bezScaleKey;
	ILinPoint3Key   linPosKey;
	ILinRotKey      linRotKey;
	ILinScaleKey    linScaleKey;

	// Get the first node in the selection set
	if (!CMaxEnv::singleton().m_pInterace->GetSelNodeCount()) 
		return;
	n = CMaxEnv::singleton().m_pInterace->GetSelNode(0); 

	// --- Process the position keys ---
	c = n->GetTMController()->GetPositionController();
	ikeys = GetKeyControlInterface(c);

	if (!ikeys) 
	{
		// No interface available to access the keys...
		// Just sample the controller to get the position
		// data at each key...
		SampleController(n, c);
		return; 
	}

	numKeys = ikeys->GetNumKeys();
	DebugPrint(_T("\nThere are %d position key(s)"), numKeys);
	if (c->ClassID() == Class_ID(TCBINTERP_POSITION_CLASS_ID, 0)) 
	{
		for (i = 0; i < numKeys; i++) 
		{
			ikeys->GetKey(i, &tcbPosKey);
			//DebugPrint(_T("\nTCB Position Key: %d=(%.1f, %.1f, %.1f)"), 
			//	i, tcbPosKey.val.x, tcbPosKey.val.y, tcbPosKey.val.z);
		}
	}
	else if (c->ClassID() == Class_ID(HYBRIDINTERP_POSITION_CLASS_ID, 0)) 
	{
		for (i = 0; i < numKeys; i++) 
		{
			ikeys->GetKey(i, &bezPosKey);
			//DebugPrint(_T("\nBezier Position Key: %d=(%.1f, %.1f, %.1f)"), 
			//	i, bezPosKey.val.x, bezPosKey.val.y, bezPosKey.val.z);

		}
	}
	else if (c->ClassID() == Class_ID(LININTERP_POSITION_CLASS_ID, 0)) 
	{
		for (i = 0; i < numKeys; i++) 
		{
			ikeys->GetKey(i, &linPosKey);
			//DebugPrint(_T("\nLinear Position Key: %d=(%.1f, %.1f, %.1f)"), 
			//	i, linPosKey.val.x, linPosKey.val.y, linPosKey.val.z);
		}
	}
	// --- Process the rotation keys ---

	c = n->GetTMController()->GetRotationController();
	ikeys = GetKeyControlInterface(c);
	if (!ikeys) return;
	numKeys = ikeys->GetNumKeys();
	//DebugPrint(_T("\nThere are %d rotation key(s)"), numKeys);
	if (c->ClassID() == Class_ID(TCBINTERP_ROTATION_CLASS_ID, 0)) 
	{
		for (i = 0; i < numKeys; i++) 
		{
			ikeys->GetKey(i, &tcbRotKey);
			newQuat = QFromAngAxis(tcbRotKey.val.angle, tcbRotKey.val.axis);
			if (i) newQuat = prevQuat * newQuat;
			prevQuat = newQuat;
			//DebugPrint(_T("\nTCB Rotation Key: %d=(%.1f, %.1f, %.1f, %.1f)"), 
			//	i, newQuat.x, newQuat.y, newQuat.z, newQuat.w);
		}
	}
	else if (c->ClassID() == Class_ID(HYBRIDINTERP_ROTATION_CLASS_ID, 0)) 
	{
		for (i = 0; i < numKeys; i++) 
		{
			ikeys->GetKey(i, &bezRotKey);
			newQuat = bezRotKey.val;
			if (i) 
				newQuat = prevQuat * newQuat;

			prevQuat = newQuat;
			//DebugPrint(_T("\nBezier Rotation Key: %d=(%.1f, %.1f, %.1f, %.1f)"), 
			//	i, newQuat.x, newQuat.y, newQuat.z, newQuat.w);
		}
	}
	else if (c->ClassID() == Class_ID(LININTERP_ROTATION_CLASS_ID, 0)) 
	{
		for (i = 0; i < numKeys; i++) 
		{
			ikeys->GetKey(i, &linRotKey);
			newQuat = linRotKey.val;
			if (i) 
				newQuat = prevQuat * newQuat;

			prevQuat = newQuat;
			//DebugPrint(_T("\nLinear Rotation Key: %d=(%.1f, %.1f, %.1f, %.1f)"), 
			//	i, newQuat.x, newQuat.y, newQuat.z, newQuat.w);
		}
	}

	// --- Process the scale keys ---
	c = n->GetTMController()->GetScaleController();
	ikeys = GetKeyControlInterface(c);

	if (!ikeys) return;

	numKeys = ikeys->GetNumKeys();
	
	//DebugPrint(_T("\nThere are %d scale key(s)"), numKeys);



	if (c->ClassID() == Class_ID(TCBINTERP_SCALE_CLASS_ID, 0)) 
	{

		for (i = 0; i < numKeys; i++) 
		{
			ikeys->GetKey(i, &tcbScaleKey);
			//DebugPrint(_T("\nTCB Scale Key: %2d=(%.1f, %.1f, %.1f)"), 
			//	i, tcbScaleKey.val.s.x, tcbScaleKey.val.s.y, 
			//	tcbScaleKey.val.s.z);
		}
	}
	else if (c->ClassID() == Class_ID(HYBRIDINTERP_SCALE_CLASS_ID, 0)) 
	{
		for (i = 0; i < numKeys; i++) 
		{
			ikeys->GetKey(i, &bezScaleKey);
			//DebugPrint(_T("\nBezier Scale Key: %2d=(%.1f, %.1f, %.1f)"), 
			//	i, bezScaleKey.val.s.x, bezScaleKey.val.s.y, 
			//	bezScaleKey.val.s.z);
		}
	}
	else if (c->ClassID() == Class_ID(LININTERP_SCALE_CLASS_ID, 0)) 
	{
		for (i = 0; i < numKeys; i++) 
		{
			ikeys->GetKey(i, &linScaleKey);
			DebugPrint(_T("\nLinear Scale Key: %2d=(%.1f, %.1f, %.1f)"), 
				i, linScaleKey.val.s.x, linScaleKey.val.s.y, 
				linScaleKey.val.s.z);
		}
	}
}
Ejemplo n.º 9
0
//BOOL TbsAnimObj::IsKnownController(Control* cont)
//{
//	ulong partA, partB;
//
//	if (!cont)
//		return FALSE;
//
////Listed below are the first ULONG of the 8 byte ID. 
////The second ULONG is 0 for all built-in classes (unless noted otherwise). 
////For example a Class_ID for a TriObject would read:
////Class_ID(TRIOBJ_CLASS_ID, 0);
////Note that only built-in classes should have the second ULONG equal to 0.
////All plug-in developers should use both ULONGs.
//
//
//	// ClassID는 두개의 ULONG변수로 구성되며 내장된 클래스들은 모두 두번째 
//	// 변수는 0의 값을 갖고 있다. 
//	// 단, 개발자의 플로그인은 두번째 값을 갖게 된다.
//	partA = cont->ClassID().PartA();
//	partB = cont->ClassID().PartB();
//
//	if (partB != 0x00)
//		return FALSE;
//
//	switch (partA) {
//		case TCBINTERP_POSITION_CLASS_ID:
//		case TCBINTERP_ROTATION_CLASS_ID:
//		case TCBINTERP_SCALE_CLASS_ID:
//		case HYBRIDINTERP_POSITION_CLASS_ID:
//		case HYBRIDINTERP_ROTATION_CLASS_ID:
//		case HYBRIDINTERP_SCALE_CLASS_ID:
//		case LININTERP_POSITION_CLASS_ID:
//		case LININTERP_ROTATION_CLASS_ID:
//		case LININTERP_SCALE_CLASS_ID:
//			return TRUE;
//	}
//
//	return FALSE;
//}
void TbsAnimObj::DumpFloatKeys(Control* cont, TMesh* pMesh) 
{
	if (!cont)		return;	
	int i;	
	IKeyControl *ikc = NULL;	
	ikc = GetKeyControlInterface(cont);
	
	TAnimTrack Anim;

	// TCB float
	if (ikc && cont->ClassID() == Class_ID(TCBINTERP_FLOAT_CLASS_ID, 0)) 
	{		
		for (i=0; i<ikc->GetNumKeys(); i++) 
		{
			ITCBFloatKey key;
			ikc->GetKey(i, &key);	
			Anim.iTick = key.time;
			Anim.vValue.x = key.val;
			pMesh->m_VisTrack.push_back( Anim );
		}		
	}
	// Bezier float
	else if (ikc && cont->ClassID() == Class_ID(HYBRIDINTERP_FLOAT_CLASS_ID, 0)) {		
		for (i=0; i<ikc->GetNumKeys(); i++) {
			IBezFloatKey key;
			ikc->GetKey(i, &key);	
			Anim.iTick = key.time;
			Anim.vValue.x = key.val;
			pMesh->m_VisTrack.push_back( Anim );
			
		}		
	}
	else if (ikc && cont->ClassID() == Class_ID(LININTERP_FLOAT_CLASS_ID, 0)) {		
		for (i=0; i<ikc->GetNumKeys(); i++) 
		{
			ILinFloatKey key;
			ikc->GetKey(i, &key);		
			Anim.iTick = key.time;
			Anim.vValue.x = key.val;
			pMesh->m_VisTrack.push_back( Anim );
		}		
	}
	else 
	{
		TSTR name;
		cont->GetClassName(name);
		
		// If it is animated at all...
		if (cont->IsAnimated()) {
			// Get the range of the controller animation 
			Interval range; 
			// Get range of full animation
			Interval animRange = m_p3dsMax->GetAnimRange(); 
			TimeValue t = cont->GetTimeRange(TIMERANGE_ALL).Start();
			float value;
			
			// While we are inside the animation... 
			while (animRange.InInterval(t)) 
			{
				// Sample the controller
				range = FOREVER;
				cont->GetValue(t, &value, range);
				
				// Set time to start of controller validity interval 
				t = range.Start();
				
				Anim.iTick = t;
				Anim.vValue.x = value;
				pMesh->m_VisTrack.push_back( Anim );
						
				if (range.End() > cont->GetTimeRange(TIMERANGE_ALL).End()) 
				{
					break;
				}
				else 
				{
					//t = (range.End()/GetTicksPerFrame()+GetKeyFrameStep()) * GetTicksPerFrame();
					t = (range.End()/GetTicksPerFrame()) * GetTicksPerFrame();
				}
			}
		}		
	}
}
Ejemplo n.º 10
0
void bgAnimMax::DumpFloatKeys(Control* pControl, bgMesh* pMesh)
{
	if (!pControl)
		return;

	int i;
	bgAnimTrack Anim;
	IKeyControl *ikc = NULL;

	ikc = GetKeyControlInterface(pControl);
	if (ikc && pControl->ClassID() == Class_ID(TCBINTERP_FLOAT_CLASS_ID, 0))
	{
		for (i = 0; i < ikc->GetNumKeys(); i++)
		{
			ITCBFloatKey key;
			ikc->GetKey(i, &key);
			Anim.iTick = key.time;
			Anim.vValue.x = key.val;
			pMesh->AlpTrack.push_back(Anim);
		}
	}
	else if (ikc && pControl->ClassID() == Class_ID(HYBRIDINTERP_FLOAT_CLASS_ID, 0))
	{
		for (i = 0; i < ikc->GetNumKeys(); i++)
		{
			IBezFloatKey key;
			ikc->GetKey(i, &key);
			Anim.iTick = key.time;
			Anim.vValue.x = key.val;
			pMesh->AlpTrack.push_back(Anim);
		}
	}
	else if (ikc && pControl->ClassID() == Class_ID(LININTERP_FLOAT_CLASS_ID, 0))
	{
		for (i = 0; i < ikc->GetNumKeys(); i++)
		{
			ILinFloatKey key;
			ikc->GetKey(i, &key);
			Anim.iTick = key.time;
			Anim.vValue.x = key.val;
			pMesh->AlpTrack.push_back(Anim);
		}
	}
	else
	{
		TSTR name;
		pControl->GetClassName(name);

		if (pControl->IsAnimated())
		{
			float value;
			Interval range;
			Interval animRange = m_p3DMax->GetAnimRange();
			TimeValue t = pControl->GetTimeRange(TIMERANGE_ALL).Start();

			while (animRange.InInterval(t))
			{
				range = FOREVER;
				pControl->GetValue(t, &value, range);

				t = range.Start();

				Anim.iTick = t;
				Anim.vValue.x = value;
				pMesh->AlpTrack.push_back(Anim);

				if (range.End() > pControl->GetTimeRange(TIMERANGE_ALL).End())
				{
					break;
				}
				else
				{
					t = (range.End() / GetTicksPerFrame()) * GetTicksPerFrame();
				}
			}
		}
	}
}
Ejemplo n.º 11
0
void RandKeysUtil::Apply()
	{
	BOOL timeMode   = iu->GetMajorMode()==TVMODE_EDITTIME;
	BOOL fcurveMode = iu->GetMajorMode()==TVMODE_EDITFCURVE;
	Interval iv = iu->GetTimeSelection();
	if (!doTime && !doVal) return;

	theHold.Begin();

	// Turn animation on
	SuspendAnimate();
	AnimateOn();

	for (int i=0; i<iu->GetNumTracks(); i++) {
		if ((timeMode||fcurveMode) && !iu->IsSelected(i)) continue;
		
		// Get Interfaces
		Animatable *anim   = iu->GetAnim(i);
		Animatable *client = iu->GetClient(i);
		int subNum         = iu->GetSubNum(i);
		Control *cont      = GetControlInterface(anim);
		IKeyControl *ikc   = GetKeyControlInterface(anim);
		IKey *key          = GetKeyPointer(anim->SuperClassID(),anim->ClassID());				
		if (!ikc || !cont || !key) continue;						
		if (fcurveMode && !anim->IsCurveSelected()) continue;

		// Get the param dim
		float min = negVal, max = posVal;
		ParamDimension *dim = client->GetParamDimension(subNum);
		if (dim) {
			min = dim->UnConvert(min);
			max = dim->UnConvert(max);
			}

		for (int j=0; j<ikc->GetNumKeys(); j++) {
			// Get the key data
			ikc->GetKey(j,key);
			
			// Check if it's selected
			if (timeMode && !iv.InInterval(key->time)) continue;
			if (!timeMode && !(key->flags&IKEY_SELECTED)) continue;			

			// Randomize time
			if (doTime) {
				key->time = (int)CompRand(
					float(key->time-negTime),
					float(key->time+posTime));
				ikc->SetKey(j,key);
				}
			}

		if (doTime) ikc->SortKeys();

		for (j=0; j<ikc->GetNumKeys(); j++) {
			// Get the key data
			ikc->GetKey(j,key);
			
			// Check if it's selected
			if (timeMode && !iv.InInterval(key->time)) continue;
			if (!timeMode && !(key->flags&IKEY_SELECTED)) continue;			

			// Randomize value
			if (doVal) {
				Point3 pt, ang;
				Point4 p4;
				float f;
				Quat q;
				ScaleValue s;				
				BOOL doX, doY, doZ, doW;
				doX = doY = doZ = doW = TRUE;
				if (!fcurveMode) {
					if (!(key->flags&IKEY_XSEL)) doX = FALSE;
					if (!(key->flags&IKEY_YSEL)) doY = FALSE;
					if (!(key->flags&IKEY_ZSEL)) doZ = FALSE;
					if (!(key->flags&IKEY_WSEL)) doW = FALSE;
					}

				switch (anim->SuperClassID()) {
					case CTRL_FLOAT_CLASS_ID:			
						cont->GetValue(key->time,&f,FOREVER);
						f = CompRand(f-min,f+max);
						cont->SetValue(key->time,&f);
						break;

					case CTRL_POSITION_CLASS_ID:
					case CTRL_POINT3_CLASS_ID:
						cont->GetValue(key->time,&pt,FOREVER);
						if (doX) pt.x = CompRand(pt.x-min,pt.x+max);
						if (doY) pt.y = CompRand(pt.y-min,pt.y+max);
						if (doZ) pt.z = CompRand(pt.z-min,pt.z+max);
						cont->SetValue(key->time,&pt);
						break;
					
					case CTRL_POINT4_CLASS_ID:
						cont->GetValue(key->time,&p4,FOREVER);
						if (doX) p4.x = CompRand(p4.x-min,p4.x+max);
						if (doY) p4.y = CompRand(p4.y-min,p4.y+max);
						if (doZ) p4.z = CompRand(p4.z-min,p4.z+max);
						if (doW) p4.w = CompRand(p4.w-min,p4.w+max);
						cont->SetValue(key->time,&p4);
						break;

					case CTRL_ROTATION_CLASS_ID:
						cont->GetValue(key->time,&q,FOREVER);
						QuatToEuler(q, ang);
						ang.x = CompRand(ang.x-min,ang.x+max);
						ang.y = CompRand(ang.y-min,ang.y+max);
						ang.z = CompRand(ang.z-min,ang.z+max);
						EulerToQuat(ang,q);
						cont->SetValue(key->time,&q);
						break;

					case CTRL_SCALE_CLASS_ID:
						cont->GetValue(key->time,&s,FOREVER);
						if (doX) s.s.x = CompRand(s.s.x-min,s.s.x+max);
						if (doY) s.s.y = CompRand(s.s.y-min,s.s.y+max);
						if (doZ) s.s.z = CompRand(s.s.z-min,s.s.z+max);
						cont->SetValue(key->time,&s);
						break;
					}
				}
			}

		
		}

	ResumeAnimate();

	theHold.Accept(GetString(IDS_RB_RANDOMIZEKEYS));
	ip->RedrawViews(ip->GetTime());
	}