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//- // ========================================================================== // Copyright 1995,2006,2008 Autodesk, Inc. All rights reserved. // // Use of this software is subject to the terms of the Autodesk // license agreement provided at the time of installation or download, // or which otherwise accompanies this software in either electronic // or hard copy form. // ========================================================================== //+ // // apiMeshShapeUI.cpp // #include <maya/MIOStream.h> #include <apiMeshShapeUI.h> #include <maya/MMaterial.h> #include <maya/MColor.h> #include <maya/MDrawData.h> #include <maya/MMatrix.h> #include <maya/MFnSingleIndexedComponent.h> #include <maya/MObjectArray.h> #include <maya/MDagPath.h> // for user interaction performance example code. (search on // "userChangingViewContext") #include <maya/MGlobal.h> #include <maya/MTextureEditorDrawInfo.h> // Object and component color defines // #define LEAD_COLOR 18 // green #define ACTIVE_COLOR 15 // white #define ACTIVE_AFFECTED_COLOR 8 // purple #define DORMANT_COLOR 4 // blue #define HILITE_COLOR 17 // pale blue #define DORMANT_VERTEX_COLOR 8 // purple #define ACTIVE_VERTEX_COLOR 16 // yellow // Vertex point size // #define POINT_SIZE 2.0 #define UV_POINT_SIZE 4.0 // // UI implementation // apiMeshUI::apiMeshUI() {} apiMeshUI::~apiMeshUI() {} void* apiMeshUI::creator() { return new apiMeshUI(); } // // Overrides // /* override */ void apiMeshUI::getDrawRequests( const MDrawInfo & info, bool objectAndActiveOnly, MDrawRequestQueue & queue ) // // Description: // // Add draw requests to the draw queue // // Arguments: // // info - current drawing state // objectsAndActiveOnly - no components if true // queue - queue of draw requests to add to // { // Get the data necessary to draw the shape // MDrawData data; apiMesh* meshNode = (apiMesh*)surfaceShape(); apiMeshGeom * geom = meshNode->meshGeom(); if ( (NULL == geom) || (0 == geom->faceCount) ) { cerr << "NO DrawRequest for apiMesh\n"; return; } // This call creates a prototype draw request that we can fill // in and then add to the draw queue. // MDrawRequest request = info.getPrototype( *this ); getDrawData( geom, data ); request.setDrawData( data ); // Decode the draw info and determine what needs to be drawn // M3dView::DisplayStyle appearance = info.displayStyle(); M3dView::DisplayStatus displayStatus = info.displayStatus(); // Are we displaying meshes? if ( ! info.objectDisplayStatus( M3dView::kDisplayMeshes ) ) return; // Use this code to help speed up drawing. // inUserInteraction() is true for any interaction with // the viewport, including object or component TRS and camera changes. // userChangingViewContext() is true only when the user is using view // context tools (tumble, dolly, track, etc.) // if ( info.inUserInteraction() || info.userChangingViewContext() ) { // User is using view context tools so // request fast draw and get out // request.setToken( kDrawRedPointAtCenter ); queue.add( request ); return; } switch ( appearance ) { case M3dView::kWireFrame : { request.setToken( kDrawWireframe ); M3dView::ColorTable activeColorTable = M3dView::kActiveColors; M3dView::ColorTable dormantColorTable = M3dView::kDormantColors; switch ( displayStatus ) { case M3dView::kLead : request.setColor( LEAD_COLOR, activeColorTable ); break; case M3dView::kActive : request.setColor( ACTIVE_COLOR, activeColorTable ); break; case M3dView::kActiveAffected : request.setColor( ACTIVE_AFFECTED_COLOR, activeColorTable ); break; case M3dView::kDormant : request.setColor( DORMANT_COLOR, dormantColorTable ); break; case M3dView::kHilite : request.setColor( HILITE_COLOR, activeColorTable ); break; default: break; } queue.add( request ); break; } case M3dView::kGouraudShaded : { // Create the smooth shaded draw request // request.setToken( kDrawSmoothShaded ); // Need to get the material info // MDagPath path = info.multiPath(); // path to your dag object M3dView view = info.view();; // view to draw to MMaterial material = MPxSurfaceShapeUI::material( path ); // If the user currently has the default material enabled on the // view then use the default material for shading. // if ( view.usingDefaultMaterial() ) { material = MMaterial::defaultMaterial(); } // Evaluate the material and if necessary, the texture. // if ( ! material.evaluateMaterial( view, path ) ) { cerr << "Couldnt evaluate\n"; } bool drawTexture = true; if ( drawTexture && material.materialIsTextured() ) { material.evaluateTexture( data ); } request.setMaterial( material ); // request.setDisplayStyle( appearance ); bool materialTransparent = false; material.getHasTransparency( materialTransparent ); if ( materialTransparent ) { request.setIsTransparent( true ); } queue.add( request ); // create a draw request for wireframe on shaded if // necessary. // if ( (displayStatus == M3dView::kActive) || (displayStatus == M3dView::kLead) || (displayStatus == M3dView::kHilite) ) { MDrawRequest wireRequest = info.getPrototype( *this ); wireRequest.setDrawData( data ); wireRequest.setToken( kDrawWireframeOnShaded ); wireRequest.setDisplayStyle( M3dView::kWireFrame ); M3dView::ColorTable activeColorTable = M3dView::kActiveColors; switch ( displayStatus ) { case M3dView::kLead : wireRequest.setColor( LEAD_COLOR, activeColorTable ); break; case M3dView::kActive : wireRequest.setColor( ACTIVE_COLOR, activeColorTable ); break; case M3dView::kHilite : wireRequest.setColor( HILITE_COLOR, activeColorTable ); break; default: break; } queue.add( wireRequest ); } break; } case M3dView::kFlatShaded : request.setToken( kDrawFlatShaded ); queue.add( request ); break; case M3dView::kBoundingBox : request.setToken( kDrawBoundingBox ); queue.add( request ); break; default: break; } // Add draw requests for components // if ( !objectAndActiveOnly ) { // Inactive components // if ( (appearance == M3dView::kPoints) || (displayStatus == M3dView::kHilite) ) { MDrawRequest vertexRequest = info.getPrototype( *this ); vertexRequest.setDrawData( data ); vertexRequest.setToken( kDrawVertices ); vertexRequest.setColor( DORMANT_VERTEX_COLOR, M3dView::kActiveColors ); queue.add( vertexRequest ); } // Active components // if ( surfaceShape()->hasActiveComponents() ) { MDrawRequest activeVertexRequest = info.getPrototype( *this ); activeVertexRequest.setDrawData( data ); activeVertexRequest.setToken( kDrawVertices ); activeVertexRequest.setColor( ACTIVE_VERTEX_COLOR, M3dView::kActiveColors ); MObjectArray clist = surfaceShape()->activeComponents(); MObject vertexComponent = clist[0]; // Should filter list activeVertexRequest.setComponent( vertexComponent ); queue.add( activeVertexRequest ); } } } /* override */ void apiMeshUI::draw( const MDrawRequest & request, M3dView & view ) const // // Description: // // Main (OpenGL) draw routine // // Arguments: // // request - request to be drawn // view - view to draw into // { // Get the token from the draw request. // The token specifies what needs to be drawn. // int token = request.token(); switch( token ) { case kDrawWireframe : case kDrawWireframeOnShaded : drawWireframe( request, view ); break; case kDrawSmoothShaded : drawShaded( request, view ); break; case kDrawFlatShaded : // Not implemented break; case kDrawVertices : drawVertices( request, view ); break; case kDrawBoundingBox: drawBoundingBox( request, view ); break; // for userChangingViewContext example code // case kDrawRedPointAtCenter: drawRedPointAtCenter( request, view ); break; } } /* override */ bool apiMeshUI::select( MSelectInfo &selectInfo, MSelectionList &selectionList, MPointArray &worldSpaceSelectPts ) const // // 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::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( MSelectionMask::kSelectNurbsSurfaces ); MSelectionList item; item.add( selectInfo.selectPath() ); MPoint xformedPt; if ( selectInfo.singleSelection() ) { MPoint center = meshNode->boundingBox().center(); xformedPt = center; xformedPt *= selectInfo.selectPath().inclusiveMatrix(); } selectInfo.addSelection( item, xformedPt, selectionList, worldSpaceSelectPts, priorityMask, false ); } return selected; } // // Helper routines // void apiMeshUI::drawWireframe( const MDrawRequest & request, M3dView & view ) const // // Description: // // Wireframe drawing routine // // Arguments: // // request - request to be drawn // view - view to draw into // { MDrawData data = request.drawData(); apiMeshGeom * geom = (apiMeshGeom*)data.geometry(); int token = request.token(); bool wireFrameOnShaded = false; if ( kDrawWireframeOnShaded == token ) { wireFrameOnShaded = true; } view.beginGL(); // Query current state so it can be restored // bool lightingWasOn = glIsEnabled( GL_LIGHTING ) ? true : false; if ( lightingWasOn ) { glDisable( GL_LIGHTING ); } if ( wireFrameOnShaded ) { glDepthMask( false ); } // Draw the wireframe mesh // int vid = 0; for ( int i=0; i<geom->faceCount; i++ ) { glBegin( GL_LINE_LOOP ); for ( int v=0; v<geom->face_counts[i]; v++ ) { MPoint vertex = geom->vertices[ geom->face_connects[vid++] ]; glVertex3f( (float)vertex[0], (float)vertex[1], (float)vertex[2] ); } glEnd(); } // Restore the state // if ( lightingWasOn ) { glEnable( GL_LIGHTING ); } if ( wireFrameOnShaded ) { glDepthMask( true ); } view.endGL(); } void apiMeshUI::drawShaded( const MDrawRequest & request, M3dView & view ) const // // Description: // // Shaded drawing routine // // Arguments: // // request - request to be drawn // view - view to draw into // { MDrawData data = request.drawData(); apiMeshGeom * geom = (apiMeshGeom*)data.geometry(); view.beginGL(); #if defined(SGI) || defined(MESA) glEnable( GL_POLYGON_OFFSET_EXT ); #else glEnable( GL_POLYGON_OFFSET_FILL ); #endif // Set up the material // MMaterial material = request.material(); material.setMaterial( request.multiPath(), request.isTransparent() ); // Enable texturing ... // // Note, Maya does not enable texturing if useDefaultMaterial is enabled. // However, you can choose to ignore this in your draw routine. // bool drawTexture = material.materialIsTextured() && !view.usingDefaultMaterial(); if ( drawTexture ) glEnable(GL_TEXTURE_2D); // Apply the texture to the current view // if ( drawTexture ) { material.applyTexture( view, data ); } // Draw the polygons // int vid = 0; int uv_len = geom->uvcoords.uvcount(); for ( int i=0; i<geom->faceCount; i++ ) { glBegin( GL_POLYGON ); for ( int v=0; v<geom->face_counts[i]; v++ ) { MPoint vertex = geom->vertices[ geom->face_connects[vid] ]; MVector normal = geom->normals[ geom->face_connects[vid] ]; // If we are drawing the texture, make sure the coord // arrays are in bounds. if ( drawTexture ) { float u, v; int uvId1 = geom->uvcoords.uvId(vid); if ( uvId1 < uv_len ) { geom->uvcoords.getUV( uvId1, u, v ); glTexCoord2f( (GLfloat)u, (GLfloat)v ); } } glNormal3f( (float)normal[0], (float)normal[1], (float)normal[2] ); glVertex3f( (float)vertex[0], (float)vertex[1], (float)vertex[2] ); vid++; } glEnd(); } // Turn off texture mode // if ( drawTexture ) glDisable(GL_TEXTURE_2D); view.endGL(); } void apiMeshUI::drawVertices( const MDrawRequest & request, M3dView & view ) const // // Description: // // Component (vertex) drawing routine // // Arguments: // // request - request to be drawn // view - view to draw into // { MDrawData data = request.drawData(); apiMeshGeom * geom = (apiMeshGeom*)data.geometry(); view.beginGL(); // Query current state so it can be restored // bool lightingWasOn = glIsEnabled( GL_LIGHTING ) ? true : false; if ( lightingWasOn ) { glDisable( GL_LIGHTING ); } float lastPointSize; glGetFloatv( GL_POINT_SIZE, &lastPointSize ); // Set the point size of the vertices // glPointSize( POINT_SIZE ); // If there is a component specified by the draw request // then loop over comp (using an MFnComponent class) and draw the // active vertices, otherwise draw all vertices. // MObject comp = request.component(); if ( ! comp.isNull() ) { MFnSingleIndexedComponent fnComponent( comp ); for ( int i=0; i<fnComponent.elementCount(); i++ ) { int index = fnComponent.element( i ); glBegin( GL_POINTS ); MPoint vertex = geom->vertices[ index ]; glVertex3f( (float)vertex[0], (float)vertex[1], (float)vertex[2] ); glEnd(); char annotation[32]; sprintf( annotation, "%d", index ); view.drawText( annotation, vertex ); } } else { int vid = 0; for ( int i=0; i<geom->faceCount; i++ ) { glBegin( GL_POINTS ); for ( int v=0; v<geom->face_counts[i]; v++ ) { MPoint vertex = geom->vertices[ geom->face_connects[vid++] ]; glVertex3f( (float)vertex[0], (float)vertex[1], (float)vertex[2] ); } glEnd(); } } // Restore the state // if ( lightingWasOn ) { glEnable( GL_LIGHTING ); } glPointSize( lastPointSize ); view.endGL(); } void apiMeshUI::drawBoundingBox( const MDrawRequest & request, M3dView & view ) const // // Description: // // Bounding box drawing routine // // Arguments: // // request - request to be drawn // view - view to draw into // { // Get the surface shape MPxSurfaceShape *shape = surfaceShape(); if ( !shape ) return; // Get the bounding box MBoundingBox box = shape->boundingBox(); float w = (float) box.width(); float h = (float) box.height(); float d = (float) box.depth(); view.beginGL(); // Below we just two sides and then connect // the edges together MPoint minVertex = box.min(); // Draw first side glBegin( GL_LINE_LOOP ); MPoint vertex = minVertex; glVertex3f( (float)vertex[0], (float)vertex[1], (float)vertex[2] ); glVertex3f( (float)vertex[0]+w, (float)vertex[1], (float)vertex[2] ); glVertex3f( (float)vertex[0]+w, (float)vertex[1]+h, (float)vertex[2] ); glVertex3f( (float)vertex[0], (float)vertex[1]+h, (float)vertex[2] ); glVertex3f( (float)vertex[0], (float)vertex[1], (float)vertex[2] ); glEnd(); // Draw second side MPoint sideFactor(0,0,d); MPoint vertex2 = minVertex + sideFactor; glBegin( GL_LINE_LOOP ); glVertex3f( (float)vertex2[0], (float)vertex2[1], (float)vertex2[2] ); glVertex3f( (float)vertex2[0]+w, (float)vertex2[1], (float)vertex2[2] ); glVertex3f( (float)vertex2[0]+w, (float)vertex2[1]+h, (float)vertex2[2] ); glVertex3f( (float)vertex2[0], (float)vertex2[1]+h, (float)vertex2[2] ); glVertex3f( (float)vertex2[0], (float)vertex2[1], (float)vertex2[2] ); glEnd(); // Connect the edges together glBegin( GL_LINES ); glVertex3f( (float)vertex2[0], (float)vertex2[1], (float)vertex2[2] ); glVertex3f( (float)vertex[0], (float)vertex[1], (float)vertex[2] ); glVertex3f( (float)vertex2[0]+w, (float)vertex2[1], (float)vertex2[2] ); glVertex3f( (float)vertex[0]+w, (float)vertex[1], (float)vertex[2] ); glVertex3f( (float)vertex2[0]+w, (float)vertex2[1]+h, (float)vertex2[2] ); glVertex3f( (float)vertex[0]+w, (float)vertex[1]+h, (float)vertex[2] ); glVertex3f( (float)vertex2[0], (float)vertex2[1]+h, (float)vertex2[2] ); glVertex3f( (float)vertex[0], (float)vertex[1]+h, (float)vertex[2] ); glEnd(); view.endGL(); } // for userChangingViewContext example code // void apiMeshUI::drawRedPointAtCenter( const MDrawRequest & request, M3dView & view ) const // // Description: // // Simple very fast draw routine // // Arguments: // // request - request to be drawn // view - view to draw into // { // Draw point // view.beginGL(); // save state // glPushAttrib( GL_CURRENT_BIT | GL_POINT_BIT ); glPointSize( 20.0f ); glBegin( GL_POINTS ); glColor3f( 1.0f, 0.0f, 0.0f ); glVertex3f(0.0f, 0.0f, 0.0f ); glEnd(); // restore state // glPopAttrib(); view.endGL(); } bool apiMeshUI::selectVertices( MSelectInfo &selectInfo, MSelectionList &selectionList, MPointArray &worldSpaceSelectPts ) const // // 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; MPoint selectionPoint; double z,previousZ = 0.0; int closestPointVertexIndex = -1; const MDagPath & path = selectInfo.multiPath(); // Create a component that will store the selected vertices // MFnSingleIndexedComponent fnComponent; MObject surfaceComponent = fnComponent.create( MFn::kMeshVertComponent ); int 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; MPoint singlePoint; bool singleSelection = selectInfo.singleSelection(); if( singleSelection ) { alignmentMatrix = selectInfo.getAlignmentMatrix(); } // 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 // int numVertices = geom->vertices.length(); for ( vertexIndex=0; vertexIndex<numVertices; vertexIndex++ ) { MPoint currentPoint = geom->vertices[ vertexIndex ]; // Sets OpenGL's render mode to select and stores // selected items in a pick buffer // view.beginSelect(); glBegin( GL_POINTS ); glVertex3f( (float)currentPoint[0], (float)currentPoint[1], (float)currentPoint[2] ); glEnd(); if ( view.endSelect() > 0 ) // Hit count > 0 { selected = true; if ( singleSelection ) { xformedPoint = currentPoint; xformedPoint.homogenize(); xformedPoint*= alignmentMatrix; z = xformedPoint.z; if ( closestPointVertexIndex < 0 || z > previousZ ) { closestPointVertexIndex = vertexIndex; singlePoint = currentPoint; previousZ = z; } } else { // multiple selection, store all elements // fnComponent.addElement( 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 *= path.inclusiveMatrix(); } // Add the selected component to the selection list // if ( selected ) { MSelectionList selectionItem; selectionItem.add( path, surfaceComponent ); MSelectionMask mask( MSelectionMask::kSelectComponentsMask ); selectInfo.addSelection( selectionItem, selectionPoint, selectionList, worldSpaceSelectPts, mask, true ); } return selected; } bool apiMeshUI::canDrawUV() const // // Description: // Tells Maya that this surface shape supports uv drawing. // { apiMesh* meshNode = (apiMesh*)surfaceShape(); apiMeshGeom * geom = meshNode->meshGeom(); return geom->uvcoords.uvcount() > 0; } void apiMeshUI::drawUVWireframe( apiMeshGeom *geom, M3dView &view, const MTextureEditorDrawInfo &info ) const // // Description: // Draws the UV layout in wireframe mode. // { view.beginGL(); // Draw the polygons // int vid = 0; int vid_start = vid; for ( int i=0; i<geom->faceCount; i++ ) { glBegin( GL_LINES ); int v; vid_start = vid; for ( v=0; v<geom->face_counts[i]-1; v++ ) { float du1, dv1, du2, dv2; int uvId1 = geom->uvcoords.uvId(vid); int uvId2 = geom->uvcoords.uvId(vid+1); geom->uvcoords.getUV( uvId1, du1, dv1 ); geom->uvcoords.getUV( uvId2, du2, dv2 ); glVertex3f( (GLfloat)du1, (GLfloat)dv1, 0.0f ); glVertex3f( (GLfloat)du2, (GLfloat)dv2, 0.0f ); vid++; } float du1, dv1, du2, dv2; int uvId1 = geom->uvcoords.uvId(vid); int uvId2 = geom->uvcoords.uvId(vid_start); geom->uvcoords.getUV( uvId1, du1, dv1 ); geom->uvcoords.getUV( uvId2, du2, dv2 ); glVertex3f( (GLfloat)du1, (GLfloat)dv1, 0.0f ); glVertex3f( (GLfloat)du2, (GLfloat)dv2, 0.0f ); vid ++ ; glEnd(); } } void apiMeshUI::drawUVMapCoord( M3dView &view, int uv, float u, float v, bool drawNum ) const // // Description: // Draw the specified uv value into the port view. If drawNum is true // It will also draw the UV id for the the UV. // { if ( drawNum ) { char s[32]; sprintf( s, "%d", uv ); view.drawText( s, MPoint( u, v, 0 ), M3dView::kCenter ); } glVertex3f( (GLfloat)u, (GLfloat)v, 0.0f ); } void apiMeshUI::drawUVMapCoordNum( apiMeshGeom *geom, M3dView &view, const MTextureEditorDrawInfo &info, bool drawNumbers ) const // // Description: // Draw the UV points for all uvs on this surface shape. // { view.beginGL(); GLfloat ptSize; glGetFloatv( GL_POINT_SIZE, &ptSize ); glPointSize( UV_POINT_SIZE ); int uv; int uv_len = geom->uvcoords.uvcount(); for ( uv = 0; uv < uv_len; uv ++ ) { float du, dv; geom->uvcoords.getUV( uv, du, dv ); drawUVMapCoord( view, uv, du, dv, drawNumbers ); } glPointSize( ptSize ); view.endGL(); } void apiMeshUI::drawUV( M3dView &view, const MTextureEditorDrawInfo &info ) const // // Description: // Main entry point for UV drawing. This method is called by the UV // texture editor when the shape is 'active'. // // Input: // A 3dView. // { apiMesh* meshNode = (apiMesh*)surfaceShape(); apiMeshGeom * geom = meshNode->meshGeom(); view.setDrawColor( MColor( 1.0f, 0.0f, 0.0f ) ); switch( info.drawingFunction() ) { case MTextureEditorDrawInfo::kDrawWireframe: drawUVWireframe( geom, view, info ); break; case MTextureEditorDrawInfo::kDrawEverything: case MTextureEditorDrawInfo::kDrawUVForSelect: drawUVWireframe( geom, view, info ); drawUVMapCoordNum( geom, view, info, false ); break; case MTextureEditorDrawInfo::kDrawVertexForSelect: case MTextureEditorDrawInfo::kDrawEdgeForSelect: case MTextureEditorDrawInfo::kDrawFacetForSelect: default: drawUVWireframe( geom, view, info ); }; }