// Main selection routine
//
public override bool select(MSelectInfo selectInfo,
MSelectionList selectionList,
MPointArray worldSpaceSelectPts)
//
// Description:
//
// Main selection routine
//
// Arguments:
//
// selectInfo - the selection state information
// selectionList - the list of selected items to add to
// worldSpaceSelectPts -
//
{
bool selected = false;
bool componentSelected = false;
bool hilited = false;
hilited = (selectInfo.displayStatus == M3dView.DisplayStatus.kHilite);
if (hilited)
{
componentSelected = selectVertices(selectInfo, selectionList,
worldSpaceSelectPts);
selected = selected || componentSelected;
}
if (!selected)
{
apiMesh meshNode = (apiMesh)surfaceShape;
// NOTE: If the geometry has an intersect routine it should
// be called here with the selection ray to determine if the
// the object was selected.
selected = true;
MSelectionMask priorityMask = new MSelectionMask(MSelectionMask.SelectionType.kSelectNurbsSurfaces);
MSelectionList item = new MSelectionList();
item.add(selectInfo.selectPath);
MPoint xformedPt = new MPoint();
if (selectInfo.singleSelection)
{
MPoint center = meshNode.boundingBox().center;
xformedPt = center;
xformedPt.multiplyEqual(selectInfo.selectPath.inclusiveMatrix);
}
selectInfo.addSelection(item, xformedPt, selectionList,
worldSpaceSelectPts, priorityMask, false);
}
return(selected);
}
//
// Description
//
// Transforms the given components. This method is used by
// the move, rotate, and scale tools in component mode when the
// tweaks for the shape are stored on a separate tweak node.
// The bounding box has to be updated here, so do the normals and
// any other attributes that depend on vertex positions.
//
// Arguments
// mat - matrix to transform the components by
// componentList - list of components to be transformed,
// or an empty list to indicate the whole surface
// cachingMode - how to use the supplied pointCache
// pointCache - if non-null, save or restore points from this list base
// on the cachingMode
// handle - handle to the attribute on the tweak node where the
// tweaks should be stored
//
public override void tweakUsing( MMatrix mat,
MObjectArray componentList,
MVertexCachingMode cachingMode,
MPointArray pointCache,
MArrayDataHandle handle)
{
apiMeshGeom geomPtr = meshGeom();
bool savePoints = (cachingMode == MVertexCachingMode.kSavePoints);
bool updatePoints = (cachingMode == MVertexCachingMode.kUpdatePoints);
MArrayDataBuilder builder = handle.builder();
MPoint delta = new MPoint();
MPoint currPt = new MPoint();
MPoint newPt = new MPoint();
int i=0;
uint len = componentList.length;
int cacheIndex = 0;
uint cacheLen = (null != pointCache) ? pointCache.length : 0;
if (cachingMode == MVertexCachingMode.kRestorePoints) {
// restore points from the pointCache
//
if (len > 0) {
// traverse the component list
//
for ( i=0; i<len; i++ )
{
MObject comp = componentList[i];
MFnSingleIndexedComponent fnComp = new MFnSingleIndexedComponent( comp );
int elemCount = fnComp.elementCount;
for ( int idx=0; idx<elemCount && cacheIndex < cacheLen; idx++, cacheIndex++) {
int elemIndex = fnComp.element( idx );
MDataHandle hdl = builder.addElement((uint)elemIndex);
double[] pt = hdl.Double3;
MPoint cachePt = pointCache[cacheIndex];
pt[0] += cachePt.x;
pt[1] += cachePt.y;
pt[2] += cachePt.z;
hdl.Double3 = pt;
}
}
} else {
// if the component list is of zero-length, it indicates that we
// should transform the entire surface
//
len = geomPtr.vertices.length;
for ( uint idx = 0; idx < len && idx < cacheLen; ++idx ) {
MDataHandle hdl = builder.addElement(idx);
double[] pt = hdl.Double3;
MPoint cachePt = pointCache[cacheIndex];
pt[0] += cachePt.x;
pt[1] += cachePt.y;
pt[2] += cachePt.z;
hdl.Double3 = pt;
}
}
} else {
// Tweak the points. If savePoints is true, also save the tweaks in the
// pointCache. If updatePoints is true, add the new tweaks to the existing
// data in the pointCache.
//
if (len > 0) {
for ( i=0; i<len; i++ )
{
MObject comp = componentList[i];
MFnSingleIndexedComponent fnComp = new MFnSingleIndexedComponent( comp );
int elemCount = fnComp.elementCount;
if (savePoints) {
pointCache.sizeIncrement = (uint)elemCount;
}
for ( int idx=0; idx<elemCount; idx++ )
{
int elemIndex = fnComp.element( idx );
MDataHandle hdl = builder.addElement((uint)elemIndex);
double[] pt = hdl.Double3;
currPt = newPt = geomPtr.vertices[elemIndex];
newPt.multiplyEqual( mat );
delta.x = newPt.x - currPt.x;
delta.y = newPt.y - currPt.y;
delta.z = newPt.z - currPt.z;
pt[0] += delta.x;
pt[1] += delta.y;
pt[2] += delta.z;
hdl.Double3 = pt;
if (savePoints) {
// store the points in the pointCache for undo
//
pointCache.append(delta*(-1.0));
} else if (updatePoints && cacheIndex < cacheLen) {
MPoint cachePt = pointCache[cacheIndex];
cachePt[0] -= delta.x;
cachePt[1] -= delta.y;
cachePt[2] -= delta.z;
cacheIndex++;
}
}
}
} else {
// if the component list is of zero-length, it indicates that we
// should transform the entire surface
//
len = geomPtr.vertices.length;
if (savePoints) {
pointCache.sizeIncrement = len;
}
for ( int idx = 0; idx < len; ++idx ) {
MDataHandle hdl = builder.addElement((uint)idx);
double[] pt = hdl.Double3;
currPt = newPt = geomPtr.vertices[idx];
newPt.multiplyEqual( mat );
delta.x = newPt.x - currPt.x;
delta.y = newPt.y - currPt.y;
delta.z = newPt.z - currPt.z;
pt[0] += delta.x;
pt[1] += delta.y;
pt[2] += delta.z;
hdl.Double3 = pt;
if (savePoints) {
// store the points in the pointCache for undo
//
pointCache.append(delta*-1.0);
} else if (updatePoints && idx < cacheLen) {
MPoint cachePt = pointCache[idx];
cachePt[0] -= delta.x;
cachePt[1] -= delta.y;
cachePt[2] -= delta.z;
}
}
}
}
// Set the builder into the handle.
//
handle.set(builder);
// Tell Maya the bounding box for this object has changed
// and thus "boundingBox()" needs to be called.
//
childChanged( MChildChanged.kBoundingBoxChanged );
}
public override void tweakUsing( MMatrix mat,
MObjectArray componentList,
MVertexCachingMode cachingMode,
MPointArray pointCache,
MArrayDataHandle handle )
//
// Description
//
// Transforms the given components. This method is used by
// the move, rotate, and scale tools in component mode when the
// tweaks for the shape are stored on a separate tweak node.
// The bounding box has to be updated here, so do the normals and
// any other attributes that depend on vertex positions.
//
// Arguments
// mat - matrix to transform the components by
// componentList - list of components to be transformed,
// or an empty list to indicate the whole surface
// cachingMode - how to use the supplied pointCache
// pointCache - if non-null, save or restore points from this list base
// on the cachingMode
// handle - handle to the attribute on the tweak node where the
// tweaks should be stored
//
{
apiMeshGeom geomPtr = meshGeom();
bool savePoints = (cachingMode == MVertexCachingMode.kSavePoints);
bool updatePoints = (cachingMode == MVertexCachingMode.kUpdatePoints);
MArrayDataBuilder builder = handle.builder();
MPoint delta = new MPoint();
MPoint currPt = new MPoint();
MPoint newPt = new MPoint();
int i=0;
uint len = componentList.length;
int cacheIndex = 0;
uint cacheLen = (null != pointCache) ? pointCache.length : 0;
if (cachingMode == MVertexCachingMode.kRestorePoints) {
// restore points from the pointCache
//
if (len > 0) {
// traverse the component list
//
for ( i=0; i<len; i++ )
{
MObject comp = componentList[i];
MFnSingleIndexedComponent fnComp = new MFnSingleIndexedComponent( comp );
int elemCount = fnComp.elementCount;
for ( int idx=0; idx<elemCount && cacheIndex < cacheLen; idx++, cacheIndex++) {
int elemIndex = fnComp.element( idx );
MDataHandle hdl = builder.addElement((uint)elemIndex);
double[] pt = hdl.Double3;
MPoint cachePt = pointCache[cacheIndex];
pt[0] += cachePt.x;
pt[1] += cachePt.y;
pt[2] += cachePt.z;
hdl.Double3 = pt;
}
}
} else {
// if the component list is of zero-length, it indicates that we
// should transform the entire surface
//
len = geomPtr.vertices.length;
for ( uint idx = 0; idx < len && idx < cacheLen; ++idx ) {
MDataHandle hdl = builder.addElement(idx);
double[] pt = hdl.Double3;
MPoint cachePt = pointCache[cacheIndex];
pt[0] += cachePt.x;
pt[1] += cachePt.y;
pt[2] += cachePt.z;
hdl.Double3 = pt;
}
}
} else {
// Tweak the points. If savePoints is true, also save the tweaks in the
// pointCache. If updatePoints is true, add the new tweaks to the existing
// data in the pointCache.
//
if (len > 0) {
for ( i=0; i<len; i++ )
{
MObject comp = componentList[i];
MFnSingleIndexedComponent fnComp = new MFnSingleIndexedComponent( comp );
int elemCount = fnComp.elementCount;
if (savePoints) {
pointCache.sizeIncrement = (uint)elemCount;
}
for ( int idx=0; idx<elemCount; idx++ )
{
int elemIndex = fnComp.element( idx );
MDataHandle hdl = builder.addElement((uint)elemIndex);
double[] pt = hdl.Double3;
currPt = newPt = geomPtr.vertices[elemIndex];
newPt.multiplyEqual( mat );
delta.x = newPt.x - currPt.x;
delta.y = newPt.y - currPt.y;
delta.z = newPt.z - currPt.z;
pt[0] += delta.x;
pt[1] += delta.y;
pt[2] += delta.z;
hdl.Double3 = pt;
if (savePoints) {
// store the points in the pointCache for undo
//
pointCache.append(delta*(-1.0));
} else if (updatePoints && cacheIndex < cacheLen) {
MPoint cachePt = pointCache[cacheIndex];
cachePt[0] -= delta.x;
cachePt[1] -= delta.y;
cachePt[2] -= delta.z;
cacheIndex++;
}
}
}
} else {
// if the component list is of zero-length, it indicates that we
// should transform the entire surface
//
len = geomPtr.vertices.length;
if (savePoints) {
pointCache.sizeIncrement = len;
}
for ( int idx = 0; idx < len; ++idx ) {
MDataHandle hdl = builder.addElement((uint)idx);
double[] pt = hdl.Double3;
currPt = newPt = geomPtr.vertices[idx];
newPt.multiplyEqual( mat );
delta.x = newPt.x - currPt.x;
delta.y = newPt.y - currPt.y;
delta.z = newPt.z - currPt.z;
pt[0] += delta.x;
pt[1] += delta.y;
pt[2] += delta.z;
hdl.Double3 = pt;
if (savePoints) {
// store the points in the pointCache for undo
//
pointCache.append(delta*-1.0);
} else if (updatePoints && idx < cacheLen) {
MPoint cachePt = pointCache[idx];
cachePt[0] -= delta.x;
cachePt[1] -= delta.y;
cachePt[2] -= delta.z;
}
}
}
}
// Set the builder into the handle.
//
handle.set(builder);
// Tell Maya the bounding box for this object has changed
// and thus "boundingBox()" needs to be called.
//
childChanged( MChildChanged.kBoundingBoxChanged );
}
//
// Description:
//
// Vertex selection.
//
// Arguments:
//
// selectInfo - the selection state information
// selectionList - the list of selected items to add to
// worldSpaceSelectPts -
//
public bool selectVertices( MSelectInfo selectInfo,
MSelectionList selectionList,
MPointArray worldSpaceSelectPts)
{
bool selected = false;
M3dView view = selectInfo.view;
MPoint xformedPoint = new MPoint();
MPoint selectionPoint = new MPoint();
double z = 0.0;
double previousZ = 0.0;
int closestPointVertexIndex = -1;
MDagPath path = selectInfo.multiPath;
// Create a component that will store the selected vertices
//
MFnSingleIndexedComponent fnComponent = new MFnSingleIndexedComponent();
MObject surfaceComponent = fnComponent.create( MFn.Type.kMeshVertComponent );
uint vertexIndex;
// if the user did a single mouse click and we find > 1 selection
// we will use the alignmentMatrix to find out which is the closest
//
MMatrix alignmentMatrix = new MMatrix();
MPoint singlePoint = new MPoint();
bool singleSelection = selectInfo.singleSelection;
if( singleSelection ) {
alignmentMatrix = selectInfo.alignmentMatrix;
}
// Get the geometry information
//
apiMesh meshNode = (apiMesh)surfaceShape;
apiMeshGeom geom = meshNode.meshGeom();
// Loop through all vertices of the mesh and
// see if they lie withing the selection area
//
uint numVertices = geom.vertices.length;
for ( vertexIndex=0; vertexIndex<numVertices; vertexIndex++ )
{
MPoint currentPoint = geom.vertices[ (int)vertexIndex ];
// Sets OpenGL's render mode to select and stores
// selected items in a pick buffer
//
view.beginSelect();
OpenGL.glBegin(OpenGL.GL_POINTS);
OpenGL.glVertex3f((float)currentPoint[0],
(float)currentPoint[1],
(float)currentPoint[2] );
OpenGL.glEnd();
if ( view.endSelect() > 0 ) // Hit count > 0
{
selected = true;
if ( singleSelection ) {
xformedPoint = currentPoint;
xformedPoint.homogenize();
xformedPoint.multiplyEqual( alignmentMatrix );
z = xformedPoint.z;
if ( closestPointVertexIndex < 0 || z > previousZ ) {
closestPointVertexIndex = (int)vertexIndex;
singlePoint = currentPoint;
previousZ = z;
}
} else {
// multiple selection, store all elements
//
fnComponent.addElement( (int)vertexIndex );
}
}
}
// If single selection, insert the closest point into the array
//
if ( selected && selectInfo.singleSelection ) {
fnComponent.addElement(closestPointVertexIndex);
// need to get world space position for this vertex
//
selectionPoint = singlePoint;
selectionPoint.multiplyEqual( path.inclusiveMatrix );
}
// Add the selected component to the selection list
//
if ( selected ) {
MSelectionList selectionItem = new MSelectionList();
selectionItem.add( path, surfaceComponent );
MSelectionMask mask = new MSelectionMask( MSelectionMask.SelectionType.kSelectComponentsMask );
selectInfo.addSelection(
selectionItem, selectionPoint,
selectionList, worldSpaceSelectPts,
mask, true );
}
return selected;
}
//
// Description:
//
// Main selection routine
//
// Arguments:
//
// selectInfo - the selection state information
// selectionList - the list of selected items to add to
// worldSpaceSelectPts -
//
// Main selection routine
//
public override bool select(MSelectInfo selectInfo,
MSelectionList selectionList,
MPointArray worldSpaceSelectPts)
{
bool selected = false;
bool componentSelected = false;
bool hilited = false;
hilited = (selectInfo.displayStatus == M3dView.DisplayStatus.kHilite);
if ( hilited ) {
componentSelected = selectVertices( selectInfo, selectionList,
worldSpaceSelectPts );
selected = selected || componentSelected;
}
if ( !selected ) {
apiMesh meshNode = (apiMesh)surfaceShape;
// NOTE: If the geometry has an intersect routine it should
// be called here with the selection ray to determine if the
// the object was selected.
selected = true;
MSelectionMask priorityMask = new MSelectionMask( MSelectionMask.SelectionType.kSelectNurbsSurfaces );
MSelectionList item = new MSelectionList();
item.add( selectInfo.selectPath );
MPoint xformedPt = new MPoint();
if ( selectInfo.singleSelection ) {
MPoint center = meshNode.boundingBox().center;
xformedPt = center;
xformedPt.multiplyEqual( selectInfo.selectPath.inclusiveMatrix );
}
selectInfo.addSelection( item, xformedPt, selectionList,
worldSpaceSelectPts, priorityMask, false );
}
return selected;
}
public bool selectVertices(MSelectInfo selectInfo,
MSelectionList selectionList,
MPointArray worldSpaceSelectPts)
//
// Description:
//
// Vertex selection.
//
// Arguments:
//
// selectInfo - the selection state information
// selectionList - the list of selected items to add to
// worldSpaceSelectPts -
//
{
bool selected = false;
M3dView view = selectInfo.view;
MPoint xformedPoint = new MPoint();
MPoint selectionPoint = new MPoint();
double z = 0.0;
double previousZ = 0.0;
int closestPointVertexIndex = -1;
MDagPath path = selectInfo.multiPath;
// Create a component that will store the selected vertices
//
MFnSingleIndexedComponent fnComponent = new MFnSingleIndexedComponent();
MObject surfaceComponent = fnComponent.create(MFn.Type.kMeshVertComponent);
uint vertexIndex;
// if the user did a single mouse click and we find > 1 selection
// we will use the alignmentMatrix to find out which is the closest
//
MMatrix alignmentMatrix = new MMatrix();
MPoint singlePoint = new MPoint();
bool singleSelection = selectInfo.singleSelection;
if (singleSelection)
{
alignmentMatrix = selectInfo.alignmentMatrix;
}
// Get the geometry information
//
apiMesh meshNode = (apiMesh)surfaceShape;
apiMeshGeom geom = meshNode.meshGeom();
// Loop through all vertices of the mesh and
// see if they lie withing the selection area
//
uint numVertices = geom.vertices.length;
for (vertexIndex = 0; vertexIndex < numVertices; vertexIndex++)
{
MPoint currentPoint = geom.vertices[(int)vertexIndex];
// Sets OpenGL's render mode to select and stores
// selected items in a pick buffer
//
view.beginSelect();
OpenGL.glBegin(OpenGL.GL_POINTS);
OpenGL.glVertex3f((float)currentPoint[0],
(float)currentPoint[1],
(float)currentPoint[2]);
OpenGL.glEnd();
if (view.endSelect() > 0) // Hit count > 0
{
selected = true;
if (singleSelection)
{
xformedPoint = currentPoint;
xformedPoint.homogenize();
xformedPoint.multiplyEqual(alignmentMatrix);
z = xformedPoint.z;
if (closestPointVertexIndex < 0 || z > previousZ)
{
closestPointVertexIndex = (int)vertexIndex;
singlePoint = currentPoint;
previousZ = z;
}
}
else
{
// multiple selection, store all elements
//
fnComponent.addElement((int)vertexIndex);
}
}
}
// If single selection, insert the closest point into the array
//
if (selected && selectInfo.singleSelection)
{
fnComponent.addElement(closestPointVertexIndex);
// need to get world space position for this vertex
//
selectionPoint = singlePoint;
selectionPoint.multiplyEqual(path.inclusiveMatrix);
}
// Add the selected component to the selection list
//
if (selected)
{
MSelectionList selectionItem = new MSelectionList();
selectionItem.add(path, surfaceComponent);
MSelectionMask mask = new MSelectionMask(MSelectionMask.SelectionType.kSelectComponentsMask);
selectInfo.addSelection(
selectionItem, selectionPoint,
selectionList, worldSpaceSelectPts,
mask, true);
}
return(selected);
}
