/* * This program source code file is part of KiCad, a free EDA CAD application. * * Copyright (C) 2015-2017 Cirilo Bernardo * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, you may find one here: * http://www.gnu.org/licenses/old-licenses/gpl-2.0.html * or you may search the http://www.gnu.org website for the version 2 license, * or you may write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA */ // Note: the board's bottom side is at Z = 0 #include #include #include #include #include #include #include #include #include "plugins/3d/3d_plugin.h" #include "plugins/3dapi/ifsg_all.h" #include "idf_parser.h" #include "vrml_layer.h" #define PLUGIN_3D_IDF_MAJOR 1 #define PLUGIN_3D_IDF_MINOR 0 #define PLUGIN_3D_IDF_PATCH 0 #define PLUGIN_3D_IDF_REVNO 0 // number of colors in the palette; cycles from 1..NCOLORS; // number 0 is special (the PCB board color) #define NCOLORS 6 // log mask for wxLogTrace #define MASK_IDF "PLUGIN_IDF" // read and instantiate an IDF component outline static SCENEGRAPH* loadIDFOutline( const wxString& aFileName ); // read and render an IDF board assembly static SCENEGRAPH* loadIDFBoard( const wxString& aFileName ); // model a single extruded outline // idxColor = color index to use // aParent = parent SCENEGRAPH object, if any static SCENEGRAPH* addOutline( IDF3_COMP_OUTLINE* outline, int idxColor, SGNODE* aParent ); // model the board extrusion static SCENEGRAPH* makeBoard( IDF3_BOARD& brd, SGNODE* aParent ); // model all included components static bool makeComponents( IDF3_BOARD& brd, SGNODE* aParent ); // model any .OTHER_OUTLINE items static bool makeOtherOutlines( IDF3_BOARD& brd, SGNODE* aParent ); // convert the IDF outline to VRML intermediate data static bool getOutlineModel( VRML_LAYER& model, const std::list< IDF_OUTLINE* >* items ); // convert IDF segment data to VRML segment data static bool addSegment( VRML_LAYER& model, IDF_SEGMENT* seg, int icont, int iseg ); // convert the VRML intermediate data into SG* data static SCENEGRAPH* vrmlToSG( VRML_LAYER& vpcb, int idxColor, SGNODE* aParent, double top, double bottom ); class LOCALESWITCH { public: LOCALESWITCH() { setlocale( LC_NUMERIC, "C" ); } ~LOCALESWITCH() { setlocale( LC_NUMERIC, "" ); } }; static SGNODE* getColor( IFSG_SHAPE& shape, int colorIdx ) { IFSG_APPEARANCE material( shape ); static int cidx = 1; int idx; if( colorIdx == -1 ) idx = cidx; else idx = colorIdx; switch( idx ) { case 0: // green for PCB material.SetSpecular( 0.13, 0.81, 0.22 ); material.SetDiffuse( 0.13, 0.81, 0.22 ); // default ambient intensity material.SetShininess( 0.3 ); break; case 1: // magenta material.SetSpecular( 0.8, 0.0, 0.8 ); material.SetDiffuse( 0.6, 0.0, 0.6 ); // default ambient intensity material.SetShininess( 0.3 ); break; case 2: // red material.SetSpecular( 0.69, 0.14, 0.14 ); material.SetDiffuse( 0.69, 0.14, 0.14 ); // default ambient intensity material.SetShininess( 0.3 ); break; case 3: // orange material.SetSpecular( 1.0, 0.44, 0.0 ); material.SetDiffuse( 1.0, 0.44, 0.0 ); // default ambient intensity material.SetShininess( 0.3 ); break; case 4: // yellow material.SetSpecular( 0.93, 0.94, 0.16 ); material.SetDiffuse( 0.93, 0.94, 0.16 ); // default ambient intensity material.SetShininess( 0.3 ); break; case 5: // blue material.SetSpecular( 0.1, 0.11, 0.88 ); material.SetDiffuse( 0.1, 0.11, 0.88 ); // default ambient intensity material.SetShininess( 0.3 ); break; default: // violet material.SetSpecular( 0.32, 0.07, 0.64 ); material.SetDiffuse( 0.32, 0.07, 0.64 ); // default ambient intensity material.SetShininess( 0.3 ); break; } if( ( colorIdx == -1 ) && ( ++cidx > NCOLORS ) ) cidx = 1; return material.GetRawPtr(); }; const char* GetKicadPluginName( void ) { return "PLUGIN_3D_IDF"; } void GetPluginVersion( unsigned char* Major, unsigned char* Minor, unsigned char* Patch, unsigned char* Revision ) { if( Major ) *Major = PLUGIN_3D_IDF_MAJOR; if( Minor ) *Minor = PLUGIN_3D_IDF_MINOR; if( Patch ) *Patch = PLUGIN_3D_IDF_PATCH; if( Revision ) *Revision = PLUGIN_3D_IDF_REVNO; return; } // number of extensions supported #ifdef _WIN32 #define NEXTS 2 #else #define NEXTS 4 #endif // number of filter sets supported #define NFILS 2 static char ext0[] = "idf"; static char ext1[] = "emn"; #ifdef _WIN32 static char fil0[] = "IDF (*.idf)|*.idf"; static char fil1[] = "IDF BRD v2/v3 (*.emn)|*.emn"; #else static char ext2[] = "IDF"; static char ext3[] = "EMN"; static char fil0[] = "IDF (*.idf;*.IDF)|*.idf;*.IDF"; static char fil1[] = "IDF BRD (*.emn;*.EMN)|*.emn;*.EMN"; #endif static struct FILE_DATA { char const* extensions[NEXTS]; char const* filters[NFILS]; FILE_DATA() { extensions[0] = ext0; extensions[1] = ext1; filters[0] = fil0; filters[1] = fil1; #ifndef _WIN32 extensions[2] = ext2; extensions[3] = ext3; #endif return; } } file_data; int GetNExtensions( void ) { return NEXTS; } char const* GetModelExtension( int aIndex ) { if( aIndex < 0 || aIndex >= NEXTS ) return NULL; return file_data.extensions[aIndex]; } int GetNFilters( void ) { return NFILS; } char const* GetFileFilter( int aIndex ) { if( aIndex < 0 || aIndex >= NFILS ) return NULL; return file_data.filters[aIndex]; } bool CanRender( void ) { // this plugin supports rendering of IDF component outlines return true; } SCENEGRAPH* Load( char const* aFileName ) { if( NULL == aFileName ) return NULL; wxFileName fname; fname.Assign( wxString::FromUTF8Unchecked( aFileName ) ); wxString ext = fname.GetExt(); SCENEGRAPH* data = NULL; if( !ext.Cmp( wxT( "idf" ) ) || !ext.Cmp( wxT( "IDF" ) ) ) { data = loadIDFOutline( fname.GetFullPath() ); } if( !ext.Cmp( wxT( "emn" ) ) || !ext.Cmp( wxT( "EMN" ) ) ) { data = loadIDFBoard( fname.GetFullPath() ); } // DEBUG: WRITE OUT IDF FILE TO CONFIRM NORMALS #if defined( DEBUG_IDF ) && DEBUG_IDF > 3 if( data ) { wxFileName fn( aFileName ); wxString output = wxT( "_idf-" ); output.append( fn.GetName() ); output.append( wxT(".wrl") ); S3D::WriteVRML( output.ToUTF8(), true, (SGNODE*)(data), true, true ); } #endif return data; } static bool getOutlineModel( VRML_LAYER& model, const std::list< IDF_OUTLINE* >* items ) { // empty outlines are not unusual so we fail quietly if( items->size() < 1 ) return false; int nvcont = 0; int iseg = 0; std::list< IDF_OUTLINE* >::const_iterator scont = items->begin(); std::list< IDF_OUTLINE* >::const_iterator econt = items->end(); std::list::iterator sseg; std::list::iterator eseg; IDF_SEGMENT lseg; while( scont != econt ) { nvcont = model.NewContour(); if( nvcont < 0 ) { #ifdef DEBUG do { std::ostringstream ostr; ostr << __FILE__ << ": " << __FUNCTION__ << ": " << __LINE__ << "\n"; ostr << " * [INFO] cannot create an outline"; wxLogTrace( MASK_IDF, "%s\n", ostr.str().c_str() ); } while( 0 ); #endif return false; } if( (*scont)->size() < 1 ) { #ifdef DEBUG do { std::ostringstream ostr; ostr << __FILE__ << ": " << __FUNCTION__ << ": " << __LINE__ << "\n"; ostr << " * [INFO] invalid contour: no vertices"; wxLogTrace( MASK_IDF, "%s\n", ostr.str().c_str() ); } while( 0 ); #endif return false; } sseg = (*scont)->begin(); eseg = (*scont)->end(); iseg = 0; while( sseg != eseg ) { lseg = **sseg; if( !addSegment( model, &lseg, nvcont, iseg ) ) { #ifdef DEBUG do { std::ostringstream ostr; ostr << __FILE__ << ": " << __FUNCTION__ << ": " << __LINE__ << "\n"; ostr << " * [BUG] cannot add segment"; wxLogTrace( MASK_IDF, "%s\n", ostr.str().c_str() ); } while( 0 ); #endif return false; } ++iseg; ++sseg; } ++scont; } return true; } static bool addSegment( VRML_LAYER& model, IDF_SEGMENT* seg, int icont, int iseg ) { // note: in all cases we must add all but the last point in the segment // to avoid redundant points if( seg->angle != 0.0 ) { if( seg->IsCircle() ) { if( iseg != 0 ) { #ifdef DEBUG do { std::ostringstream ostr; ostr << __FILE__ << ": " << __FUNCTION__ << ": " << __LINE__ << "\n"; ostr << " * [INFO] adding a circle to an existing vertex list"; wxLogTrace( MASK_IDF, "%s\n", ostr.str().c_str() ); } while( 0 ); #endif return false; } return model.AppendCircle( seg->center.x, seg->center.y, seg->radius, icont ); } else { return model.AppendArc( seg->center.x, seg->center.y, seg->radius, seg->offsetAngle, seg->angle, icont ); } } if( !model.AddVertex( icont, seg->startPoint.x, seg->startPoint.y ) ) return false; return true; } static SCENEGRAPH* vrmlToSG( VRML_LAYER& vpcb, int idxColor, SGNODE* aParent, double top, double bottom ) { vpcb.Tesselate( NULL ); std::vector< double > vertices; std::vector< int > idxPlane; std::vector< int > idxSide; if( top < bottom ) { double tmp = top; top = bottom; bottom = tmp; } if( !vpcb.Get3DTriangles( vertices, idxPlane, idxSide, top, bottom ) ) { #ifdef DEBUG do { std::ostringstream ostr; ostr << __FILE__ << ": " << __FUNCTION__ << ": " << __LINE__ << "\n"; ostr << " * [INFO] no vertex data"; wxLogTrace( MASK_IDF, "%s\n", ostr.str().c_str() ); } while( 0 ); #endif return NULL; } if( ( idxPlane.size() % 3 ) || ( idxSide.size() % 3 ) ) { #ifdef DEBUG do { std::ostringstream ostr; ostr << __FILE__ << ": " << __FUNCTION__ << ": " << __LINE__ << "\n"; ostr << " * [BUG] index lists are not a multiple of 3 (not a triangle list)"; wxLogTrace( MASK_IDF, "%s\n", ostr.str().c_str() ); } while( 0 ); #endif return NULL; } std::vector< SGPOINT > vlist; size_t nvert = vertices.size() / 3; size_t j = 0; for( size_t i = 0; i < nvert; ++i, j+= 3 ) vlist.push_back( SGPOINT( vertices[j], vertices[j+1], vertices[j+2] ) ); // create the intermediate scenegraph IFSG_TRANSFORM* tx0 = new IFSG_TRANSFORM( aParent ); // tx0 = Transform for this outline IFSG_SHAPE* shape = new IFSG_SHAPE( *tx0 ); // shape will hold (a) all vertices and (b) a local list of normals IFSG_FACESET* face = new IFSG_FACESET( *shape ); // this face shall represent the top and bottom planes IFSG_COORDS* cp = new IFSG_COORDS( *face ); // coordinates for all faces cp->SetCoordsList( nvert, &vlist[0] ); IFSG_COORDINDEX* coordIdx = new IFSG_COORDINDEX( *face ); // coordinate indices for top and bottom planes only coordIdx->SetIndices( idxPlane.size(), &idxPlane[0] ); IFSG_NORMALS* norms = new IFSG_NORMALS( *face ); // normals for the top and bottom planes // number of TOP (and bottom) vertices j = nvert / 2; // set the TOP normals for( size_t i = 0; i < j; ++i ) norms->AddNormal( 0.0, 0.0, 1.0 ); // set the BOTTOM normals for( size_t i = 0; i < j; ++i ) norms->AddNormal( 0.0, 0.0, -1.0 ); // assign a color from the palette SGNODE* modelColor = getColor( *shape, idxColor ); // create a second shape describing the vertical walls of the IDF extrusion // using per-vertex-per-face-normals shape->NewNode( *tx0 ); shape->AddRefNode( modelColor ); // set the color to be the same as the top/bottom face->NewNode( *shape ); cp->NewNode( *face ); // new vertex list norms->NewNode( *face ); // new normals list coordIdx->NewNode( *face ); // new index list // populate the new per-face vertex list and its indices and normals std::vector< int >::iterator sI = idxSide.begin(); std::vector< int >::iterator eI = idxSide.end(); size_t sidx = 0; // index to the new coord set SGPOINT p1, p2, p3; SGVECTOR vnorm; while( sI != eI ) { p1 = vlist[*sI]; cp->AddCoord( p1 ); ++sI; p2 = vlist[*sI]; cp->AddCoord( p2 ); ++sI; p3 = vlist[*sI]; cp->AddCoord( p3 ); ++sI; vnorm.SetVector( S3D::CalcTriNorm( p1, p2, p3 ) ); norms->AddNormal( vnorm ); norms->AddNormal( vnorm ); norms->AddNormal( vnorm ); coordIdx->AddIndex( (int)sidx ); ++sidx; coordIdx->AddIndex( (int)sidx ); ++sidx; coordIdx->AddIndex( (int)sidx ); ++sidx; } SCENEGRAPH* data = (SCENEGRAPH*)tx0->GetRawPtr(); // delete the API wrappers delete shape; delete face; delete coordIdx; delete cp; delete tx0; return data; } static SCENEGRAPH* addOutline( IDF3_COMP_OUTLINE* outline, int idxColor, SGNODE* aParent ) { VRML_LAYER vpcb; if( !getOutlineModel( vpcb, outline->GetOutlines() ) ) { #ifdef DEBUG do { std::ostringstream ostr; ostr << __FILE__ << ": " << __FUNCTION__ << ": " << __LINE__ << "\n"; ostr << " * [INFO] no valid outline data"; wxLogTrace( MASK_IDF, "%s\n", ostr.str().c_str() ); } while( 0 ); #endif return NULL; } vpcb.EnsureWinding( 0, false ); double top = outline->GetThickness(); double bot = 0.0; // note: some IDF entities permit negative heights if( top < bot ) { bot = top; top = 0.0; } SCENEGRAPH* data = vrmlToSG( vpcb, idxColor, aParent, top, bot ); return data; } static SCENEGRAPH* loadIDFOutline( const wxString& aFileName ) { LOCALESWITCH switcher; IDF3_BOARD brd( IDF3::CAD_ELEC ); IDF3_COMP_OUTLINE* outline = NULL; outline = brd.GetComponentOutline( aFileName ); if( NULL == outline ) { #ifdef DEBUG do { std::ostringstream ostr; ostr << __FILE__ << ": " << __FUNCTION__ << ": " << __LINE__ << "\n"; ostr << " * [INFO] Failed to read IDF data:\n"; ostr << brd.GetError() << "\n\n"; ostr << " * [INFO] no outline for file '"; ostr << aFileName << "'"; wxLogTrace( MASK_IDF, "%s\n", ostr.str().c_str() ); } while( 0 ); #endif return NULL; } SCENEGRAPH* data = addOutline( outline, -1, NULL ); return data; } static SCENEGRAPH* loadIDFBoard( const wxString& aFileName ) { LOCALESWITCH switcher; IDF3_BOARD brd( IDF3::CAD_ELEC ); // note: if the IDF model is defective no outline substitutes shall be made if( !brd.ReadFile( aFileName, true ) ) { #ifdef DEBUG do { std::ostringstream ostr; ostr << __FILE__ << ": " << __FUNCTION__ << ": " << __LINE__ << "\n"; ostr << " * [INFO] Failed to read IDF file:\n"; ostr << brd.GetError() << "\n\n"; ostr << " * [INFO] IDF file '" << aFileName.ToUTF8() << "'"; wxLogTrace( MASK_IDF, "%s\n", ostr.str().c_str() ); } while( 0 ); #endif return NULL; } IFSG_TRANSFORM tx0( true ); SGNODE* topNode = tx0.GetRawPtr(); bool noBoard = false; bool noComp = false; bool noOther = false; if( NULL == makeBoard( brd, topNode ) ) noBoard = true; if( !makeComponents( brd, topNode ) ) noComp = true; if( !makeOtherOutlines( brd, topNode ) ) noOther = true; if( noBoard && noComp && noOther ) { tx0.Destroy(); return NULL; } return (SCENEGRAPH*) topNode; } static SCENEGRAPH* makeBoard( IDF3_BOARD& brd, SGNODE* aParent ) { if( NULL == aParent ) return NULL; VRML_LAYER vpcb; // check if no board outline if( brd.GetBoardOutlinesSize() < 1 ) return NULL; if( !getOutlineModel( vpcb, brd.GetBoardOutline()->GetOutlines() ) ) return NULL; vpcb.EnsureWinding( 0, false ); int nvcont = vpcb.GetNContours() - 1; while( nvcont > 0 ) vpcb.EnsureWinding( nvcont--, true ); // Add the drill holes const std::list* drills = &brd.GetBoardDrills(); std::list::const_iterator sd = drills->begin(); std::list::const_iterator ed = drills->end(); while( sd != ed ) { vpcb.AddCircle( (*sd)->GetDrillXPos(), (*sd)->GetDrillYPos(), (*sd)->GetDrillDia() / 2.0, true ); ++sd; } std::map< std::string, IDF3_COMPONENT* >*const comp = brd.GetComponents(); std::map< std::string, IDF3_COMPONENT* >::const_iterator sc = comp->begin(); std::map< std::string, IDF3_COMPONENT* >::const_iterator ec = comp->end(); while( sc != ec ) { drills = sc->second->GetDrills(); sd = drills->begin(); ed = drills->end(); while( sd != ed ) { vpcb.AddCircle( (*sd)->GetDrillXPos(), (*sd)->GetDrillYPos(), (*sd)->GetDrillDia() / 2.0, true ); ++sd; } ++sc; } double top = brd.GetBoardThickness(); SCENEGRAPH* data = vrmlToSG( vpcb, 0, aParent, top, 0.0 ); return data; } static bool makeComponents( IDF3_BOARD& brd, SGNODE* aParent ) { if( NULL == aParent ) return false; int ncomponents = 0; double brdTop = brd.GetBoardThickness(); // Add the component outlines const std::map< std::string, IDF3_COMPONENT* >*const comp = brd.GetComponents(); std::map< std::string, IDF3_COMPONENT* >::const_iterator sc = comp->begin(); std::map< std::string, IDF3_COMPONENT* >::const_iterator ec = comp->end(); std::list< IDF3_COMP_OUTLINE_DATA* >::const_iterator so; std::list< IDF3_COMP_OUTLINE_DATA* >::const_iterator eo; double vX, vY, vA; double tX, tY, tZ, tA; bool bottom; IDF3::IDF_LAYER lyr; std::map< std::string, SGNODE* > dataMap; // map data by UID std::map< std::string, SGNODE* >::iterator dataItem; IDF3_COMP_OUTLINE* pout; while( sc != ec ) { sc->second->GetPosition( vX, vY, vA, lyr ); if( lyr == IDF3::LYR_BOTTOM ) bottom = true; else bottom = false; so = sc->second->GetOutlinesData()->begin(); eo = sc->second->GetOutlinesData()->end(); while( so != eo ) { if( std::abs( (*so)->GetOutline()->GetThickness() ) < 0.001 ) { ++so; continue; } (*so)->GetOffsets( tX, tY, tZ, tA ); tX += vX; tY += vY; tA += vA; pout = (IDF3_COMP_OUTLINE*)((*so)->GetOutline()); if( NULL == pout ) { ++so; continue; } dataItem = dataMap.find( pout->GetUID() ); SCENEGRAPH* sg = NULL; if( dataItem == dataMap.end() ) { sg = addOutline( pout, -1, NULL ); if( NULL == sg ) { ++so; continue; } ++ncomponents; dataMap.insert( std::pair< std::string, SGNODE* > ( pout->GetUID(), (SGNODE*)sg ) ); } else { sg = (SCENEGRAPH*) dataItem->second; } IFSG_TRANSFORM tx0( aParent ); IFSG_TRANSFORM txN( false ); txN.Attach( (SGNODE*)sg ); if( NULL == txN.GetParent() ) tx0.AddChildNode( txN ); else tx0.AddRefNode( txN ); if( bottom ) { tx0.SetTranslation( SGPOINT( tX, tY, -tZ ) ); // for an item on the back of the board we have a compounded rotation, // first a flip on the Y axis as per the IDF spec and then a rotation // of -tA degrees on the Z axis. The resultant rotation axis is an // XY vector equivalent to (0,1) rotated by -(tA/2) degrees // double ang = -tA * M_PI / 360.0; double sinA = sin( ang ); double cosA = cos( ang ); tx0.SetRotation( SGVECTOR( -sinA, cosA , 0 ), M_PI ); } else { tx0.SetTranslation( SGPOINT( tX, tY, tZ + brdTop ) ); tx0.SetRotation( SGVECTOR( 0, 0, 1 ), tA * M_PI / 180.0 ); } ++so; } ++sc; } if( 0 == ncomponents ) return false; return true; } static bool makeOtherOutlines( IDF3_BOARD& brd, SGNODE* aParent ) { if( NULL == aParent ) return false; VRML_LAYER vpcb; int ncomponents = 0; double brdTop = brd.GetBoardThickness(); double top, bot; // Add the component outlines const std::map< std::string, OTHER_OUTLINE* >*const comp = brd.GetOtherOutlines(); std::map< std::string, OTHER_OUTLINE* >::const_iterator sc = comp->begin(); std::map< std::string, OTHER_OUTLINE* >::const_iterator ec = comp->end(); int nvcont; OTHER_OUTLINE* pout; while( sc != ec ) { pout = sc->second; if( std::abs( pout->GetThickness() ) < 0.001 ) { ++sc; continue; } if( !getOutlineModel( vpcb, pout->GetOutlines() ) ) { vpcb.Clear(); ++sc; continue; } vpcb.EnsureWinding( 0, false ); nvcont = vpcb.GetNContours() - 1; while( nvcont > 0 ) vpcb.EnsureWinding( nvcont--, true ); if( pout->GetSide() == IDF3::LYR_BOTTOM ) { top = 0.0; bot = -pout->GetThickness(); } else { bot = brdTop; top = bot + pout->GetThickness(); } if( NULL == vrmlToSG( vpcb, -1, aParent, top, bot ) ) { vpcb.Clear(); ++sc; continue; } ++ncomponents; vpcb.Clear(); ++sc; } if( 0 == ncomponents ) return false; return true; }