/****************************************************/ /* class_module.cpp : MODULE class implementation. */ /****************************************************/ #include "fctsys.h" #include "gr_basic.h" #include "wxstruct.h" #include "common.h" #include "plot_common.h" #include "class_drawpanel.h" #include "trigo.h" #include "confirm.h" #include "kicad_string.h" #include "pcbcommon.h" #include "pcbnew.h" #include "class_board_design_settings.h" #include "colors_selection.h" #include "drag.h" #include "3d_struct.h" #include "protos.h" #include "richio.h" #include "filter_reader.h" /*********************************************/ /* Class MODULE : describes a pcb component. */ /*********************************************/ MODULE::MODULE( BOARD* parent ) : BOARD_ITEM( parent, TYPE_MODULE ) { m_Attributs = MOD_DEFAULT; m_Layer = LAYER_N_FRONT; m_Orient = 0; m_ModuleStatus = 0; flag = 0; m_CntRot90 = m_CntRot180 = 0; m_Surface = 0.0; m_Link = 0; m_LastEdit_Time = time( NULL ); m_LocalClearance = 0; m_LocalSolderMaskMargin = 0; m_LocalSolderPasteMargin = 0; m_LocalSolderPasteMarginRatio = 0.0; m_Reference = new TEXTE_MODULE( this, TEXT_is_REFERENCE ); m_Value = new TEXTE_MODULE( this, TEXT_is_VALUE ); // Reserve one void 3D entry, to avoid problems with void list m_3D_Drawings.PushBack( new S3D_MASTER( this ) ); } MODULE::~MODULE() { delete m_Reference; delete m_Value; } /* Draw the anchor cross (vertical) * Must be done after the pads, because drawing the hole will erase overwrite * every thing already drawn. */ void MODULE::DrawAncre( EDA_DRAW_PANEL* panel, wxDC* DC, const wxPoint& offset, int dim_ancre, int draw_mode ) { int anchor_size = DC->DeviceToLogicalXRel( dim_ancre ); GRSetDrawMode( DC, draw_mode ); if( GetBoard()->IsElementVisible( ANCHOR_VISIBLE ) ) { int color = g_ColorsSettings.GetItemColor( ANCHOR_VISIBLE ); GRLine( &panel->m_ClipBox, DC, m_Pos.x - offset.x - anchor_size, m_Pos.y - offset.y, m_Pos.x - offset.x + anchor_size, m_Pos.y - offset.y, 0, color ); GRLine( &panel->m_ClipBox, DC, m_Pos.x - offset.x, m_Pos.y - offset.y - anchor_size, m_Pos.x - offset.x, m_Pos.y - offset.y + anchor_size, 0, color ); } } void MODULE::Copy( MODULE* aModule ) { m_Pos = aModule->m_Pos; m_Layer = aModule->m_Layer; m_LibRef = aModule->m_LibRef; m_Attributs = aModule->m_Attributs; m_Orient = aModule->m_Orient; m_BoundaryBox = aModule->m_BoundaryBox; m_PadNum = aModule->m_PadNum; m_CntRot90 = aModule->m_CntRot90; m_CntRot180 = aModule->m_CntRot180; m_LastEdit_Time = aModule->m_LastEdit_Time; m_Link = aModule->m_Link; m_Path = aModule->m_Path; //is this correct behavior? m_TimeStamp = GetTimeStamp(); m_LocalClearance = aModule->m_LocalClearance; m_LocalSolderMaskMargin = aModule->m_LocalSolderMaskMargin; m_LocalSolderPasteMargin = aModule->m_LocalSolderPasteMargin; m_LocalSolderPasteMarginRatio = aModule->m_LocalSolderPasteMarginRatio; /* Copy reference and value. */ m_Reference->Copy( aModule->m_Reference ); m_Value->Copy( aModule->m_Value ); /* Copy auxiliary data: Pads */ m_Pads.DeleteAll(); for( D_PAD* pad = aModule->m_Pads; pad; pad = pad->Next() ) { D_PAD* newpad = new D_PAD( this ); newpad->Copy( pad ); m_Pads.PushBack( newpad ); } /* Copy auxiliary data: Drawings */ m_Drawings.DeleteAll(); for( BOARD_ITEM* item = aModule->m_Drawings; item; item = item->Next() ) { switch( item->Type() ) { case TYPE_TEXTE_MODULE: TEXTE_MODULE * textm; textm = new TEXTE_MODULE( this ); textm->Copy( (TEXTE_MODULE*) item ); m_Drawings.PushBack( textm ); break; case TYPE_EDGE_MODULE: EDGE_MODULE * edge; edge = new EDGE_MODULE( this ); edge->Copy( (EDGE_MODULE*) item ); m_Drawings.PushBack( edge ); break; default: wxMessageBox( wxT( "MODULE::Copy() Internal Err: unknown type" ) ); break; } } /* Copy auxiliary data: 3D_Drawings info */ m_3D_Drawings.DeleteAll(); // Ensure there is one (or more) item in m_3D_Drawings m_3D_Drawings.PushBack( new S3D_MASTER( this ) ); // push a void item for( S3D_MASTER* item = aModule->m_3D_Drawings; item; item = item->Next() ) { if( item->m_Shape3DName.IsEmpty() ) // do not copy empty shapes. continue; S3D_MASTER* t3d = m_3D_Drawings; if( t3d && t3d->m_Shape3DName.IsEmpty() ) // The first entry can // exist, but is empty : // use it. t3d->Copy( item ); else { t3d = new S3D_MASTER( this ); t3d->Copy( item ); m_3D_Drawings.PushBack( t3d ); } } m_Doc = aModule->m_Doc; m_KeyWord = aModule->m_KeyWord; } /** * Function Draw * Draws the footprint to the current Device Context * @param aPanel = draw panel, Used to know the clip box * @param aDC = Current Device Context * @param aDrawMode = GR_OR, GR_XOR.. * @param aOffset = draw offset (usually wxPoint(0,0) */ void MODULE::Draw( EDA_DRAW_PANEL* aPanel, wxDC* aDC, int aDrawMode, const wxPoint& aOffset ) { if( (m_Flags & DO_NOT_DRAW) || (m_Flags & IS_MOVED) ) return; for( D_PAD* pad = m_Pads; pad; pad = pad->Next() ) { if( pad->m_Flags & IS_MOVED ) continue; pad->Draw( aPanel, aDC, aDrawMode, aOffset ); } BOARD* brd = GetBoard(); // Draws footprint anchor DrawAncre( aPanel, aDC, aOffset, DIM_ANCRE_MODULE, aDrawMode ); /* Draw graphic items */ if( brd->IsElementVisible( MOD_REFERENCES_VISIBLE ) ) { if( !(m_Reference->m_Flags & IS_MOVED) ) m_Reference->Draw( aPanel, aDC, aDrawMode, aOffset ); } if( brd->IsElementVisible( MOD_VALUES_VISIBLE ) ) { if( !(m_Value->m_Flags & IS_MOVED) ) m_Value->Draw( aPanel, aDC, aDrawMode, aOffset ); } for( BOARD_ITEM* item = m_Drawings; item; item = item->Next() ) { if( item->m_Flags & IS_MOVED ) continue; switch( item->Type() ) { case TYPE_TEXTE_MODULE: case TYPE_EDGE_MODULE: item->Draw( aPanel, aDC, aDrawMode, aOffset ); break; default: break; } } } /** * Function DrawEdgesOnly * Draws the footprint edges only to the current Device Context * @param panel = The active Draw Panel (used to know the clip box) * @param DC = current Device Context * @param offset = draw offset (usually wxPoint(0,0) * @param draw_mode = GR_OR, GR_XOR, GR_AND */ void MODULE::DrawEdgesOnly( EDA_DRAW_PANEL* panel, wxDC* DC, const wxPoint& offset, int draw_mode ) { for( BOARD_ITEM* item = m_Drawings; item; item = item->Next() ) { switch( item->Type() ) { case TYPE_EDGE_MODULE: item->Draw( panel, DC, draw_mode, offset ); break; default: break; } } } bool MODULE::Save( FILE* aFile ) const { char statusTxt[8]; BOARD_ITEM* item; bool rc = false; fprintf( aFile, "$MODULE %s\n", TO_UTF8( m_LibRef ) ); memset( statusTxt, 0, sizeof(statusTxt) ); if( IsLocked() ) statusTxt[0] = 'F'; else statusTxt[0] = '~'; if( m_ModuleStatus & MODULE_is_PLACED ) statusTxt[1] = 'P'; else statusTxt[1] = '~'; fprintf( aFile, "Po %d %d %d %d %8.8lX %8.8lX %s\n", m_Pos.x, m_Pos.y, m_Orient, m_Layer, m_LastEdit_Time, m_TimeStamp, statusTxt ); fprintf( aFile, "Li %s\n", TO_UTF8( m_LibRef ) ); if( !m_Doc.IsEmpty() ) { fprintf( aFile, "Cd %s\n", TO_UTF8( m_Doc ) ); } if( !m_KeyWord.IsEmpty() ) { fprintf( aFile, "Kw %s\n", TO_UTF8( m_KeyWord ) ); } fprintf( aFile, "Sc %8.8lX\n", m_TimeStamp ); fprintf( aFile, "AR %s\n", TO_UTF8( m_Path ) ); fprintf( aFile, "Op %X %X 0\n", m_CntRot90, m_CntRot180 ); if( m_LocalSolderMaskMargin != 0 ) fprintf( aFile, ".SolderMask %d\n", m_LocalSolderMaskMargin ); if( m_LocalSolderPasteMargin != 0 ) fprintf( aFile, ".SolderPaste %d\n", m_LocalSolderPasteMargin ); if( m_LocalSolderPasteMarginRatio != 0 ) fprintf( aFile, ".SolderPasteRatio %g\n", m_LocalSolderPasteMarginRatio ); if( m_LocalClearance != 0 ) fprintf( aFile, ".LocalClearance %d\n", m_LocalClearance ); // attributes if( m_Attributs != MOD_DEFAULT ) { fprintf( aFile, "At " ); if( m_Attributs & MOD_CMS ) fprintf( aFile, "SMD " ); if( m_Attributs & MOD_VIRTUAL ) fprintf( aFile, "VIRTUAL " ); fprintf( aFile, "\n" ); } // save reference if( !m_Reference->Save( aFile ) ) goto out; // save value if( !m_Value->Save( aFile ) ) goto out; // save drawing elements for( item = m_Drawings; item; item = item->Next() ) { switch( item->Type() ) { case TYPE_TEXTE_MODULE: case TYPE_EDGE_MODULE: if( !item->Save( aFile ) ) goto out; break; default: #if defined(DEBUG) printf( "MODULE::Save() ignoring type %d\n", item->Type() ); #endif break; } } // save the pads for( item = m_Pads; item; item = item->Next() ) if( !item->Save( aFile ) ) goto out; Write_3D_Descr( aFile ); fprintf( aFile, "$EndMODULE %s\n", TO_UTF8( m_LibRef ) ); rc = true; out: return rc; } /* Save the description of 3D MODULE */ int MODULE::Write_3D_Descr( FILE* File ) const { char buf[512]; for( S3D_MASTER* t3D = m_3D_Drawings; t3D; t3D = t3D->Next() ) { if( !t3D->m_Shape3DName.IsEmpty() ) { fprintf( File, "$SHAPE3D\n" ); fprintf( File, "Na %s\n", EscapedUTF8( t3D->m_Shape3DName ).c_str() ); sprintf( buf, "Sc %lf %lf %lf\n", t3D->m_MatScale.x, t3D->m_MatScale.y, t3D->m_MatScale.z ); fprintf( File, "%s", to_point( buf ) ); sprintf( buf, "Of %lf %lf %lf\n", t3D->m_MatPosition.x, t3D->m_MatPosition.y, t3D->m_MatPosition.z ); fprintf( File, "%s", to_point( buf ) ); sprintf( buf, "Ro %lf %lf %lf\n", t3D->m_MatRotation.x, t3D->m_MatRotation.y, t3D->m_MatRotation.z ); fprintf( File, "%s", to_point( buf ) ); fprintf( File, "$EndSHAPE3D\n" ); } } return 0; } /* Read 3D module from file. (Ascii) * The 1st line of descr ($MODULE) is assumed to be already read * Returns 0 if OK */ int MODULE::Read_3D_Descr( LINE_READER* aReader ) { char* Line = aReader->Line(); char* text = Line + 3; S3D_MASTER* t3D = m_3D_Drawings; if( !t3D->m_Shape3DName.IsEmpty() ) { S3D_MASTER* n3D = new S3D_MASTER( this ); m_3D_Drawings.PushBack( n3D ); t3D = n3D; } while( aReader->ReadLine() ) { Line = aReader->Line(); switch( Line[0] ) { case '$': if( Line[1] == 'E' ) return 0; return 1; case 'N': // Shape File Name { char buf[512]; ReadDelimitedText( buf, text, 512 ); t3D->m_Shape3DName = FROM_UTF8( buf ); break; } case 'S': // Scale sscanf( text, "%lf %lf %lf\n", &t3D->m_MatScale.x, &t3D->m_MatScale.y, &t3D->m_MatScale.z ); break; case 'O': // Offset sscanf( text, "%lf %lf %lf\n", &t3D->m_MatPosition.x, &t3D->m_MatPosition.y, &t3D->m_MatPosition.z ); break; case 'R': // Rotation sscanf( text, "%lf %lf %lf\n", &t3D->m_MatRotation.x, &t3D->m_MatRotation.y, &t3D->m_MatRotation.z ); break; default: break; } } return 1; } /* Read a MODULE description * The first description line ($MODULE) is already read * @return 0 if no error */ int MODULE::ReadDescr( LINE_READER* aReader ) { char* Line; char BufLine[256], BufCar1[128], * PtLine; int itmp1, itmp2; while( aReader->ReadLine() ) { Line = aReader->Line(); if( Line[0] == '$' ) { if( Line[1] == 'E' ) break; if( Line[1] == 'P' ) { D_PAD* pad = new D_PAD( this ); pad->ReadDescr( aReader ); RotatePoint( &pad->m_Pos, m_Orient ); pad->m_Pos.x += m_Pos.x; pad->m_Pos.y += m_Pos.y; m_Pads.PushBack( pad ); continue; } if( Line[1] == 'S' ) Read_3D_Descr( aReader ); } if( strlen( Line ) < 4 ) continue; PtLine = Line + 3; /* Decode the first code of the current line and read the * corresponding data */ switch( Line[0] ) { case 'P': memset( BufCar1, 0, sizeof(BufCar1) ); sscanf( PtLine, "%d %d %d %d %lX %lX %s", &m_Pos.x, &m_Pos.y, &m_Orient, &m_Layer, &m_LastEdit_Time, &m_TimeStamp, BufCar1 ); m_ModuleStatus = 0; if( BufCar1[0] == 'F' ) SetLocked( true ); if( BufCar1[1] == 'P' ) m_ModuleStatus |= MODULE_is_PLACED; break; case 'L': /* Li = read the library name of the footprint */ *BufLine = 0; sscanf( PtLine, " %s", BufLine ); m_LibRef = FROM_UTF8( BufLine ); break; case 'S': sscanf( PtLine, " %lX", &m_TimeStamp ); break; case 'O': /* (Op)tions for auto placement */ itmp1 = itmp2 = 0; sscanf( PtLine, " %X %X", &itmp1, &itmp2 ); m_CntRot180 = itmp2 & 0x0F; if( m_CntRot180 > 10 ) m_CntRot180 = 10; m_CntRot90 = itmp1 & 0x0F; if( m_CntRot90 > 10 ) m_CntRot90 = 0; itmp1 = (itmp1 >> 4) & 0x0F; if( itmp1 > 10 ) itmp1 = 0; m_CntRot90 |= itmp1 << 4; break; case 'A': if( Line[1] == 't' ) { /* At = (At)tributes of module */ if( strstr( PtLine, "SMD" ) ) m_Attributs |= MOD_CMS; if( strstr( PtLine, "VIRTUAL" ) ) m_Attributs |= MOD_VIRTUAL; } if( Line[1] == 'R' ) { // alternate reference, e.g. /478C2408/478AD1B6 sscanf( PtLine, " %s", BufLine ); m_Path = FROM_UTF8( BufLine ); } break; case 'T': /* Read a footprint text description (ref, value, or * drawing */ TEXTE_MODULE * textm; sscanf( Line + 1, "%d", &itmp1 ); if( itmp1 == TEXT_is_REFERENCE ) textm = m_Reference; else if( itmp1 == TEXT_is_VALUE ) textm = m_Value; else /* text is a drawing */ { textm = new TEXTE_MODULE( this ); m_Drawings.PushBack( textm ); } textm->ReadDescr( aReader ); break; case 'D': /* read a drawing item */ EDGE_MODULE * edge; edge = new EDGE_MODULE( this ); m_Drawings.PushBack( edge ); edge->ReadDescr( aReader ); edge->SetDrawCoord(); break; case 'C': /* read documentation data */ m_Doc = FROM_UTF8( StrPurge( PtLine ) ); break; case 'K': /* Read key words */ m_KeyWord = FROM_UTF8( StrPurge( PtLine ) ); break; case '.': /* Read specific data */ if( strnicmp( Line, ".SolderMask ", 12 ) == 0 ) m_LocalSolderMaskMargin = atoi( Line + 12 ); else if( strnicmp( Line, ".SolderPaste ", 13 ) == 0 ) m_LocalSolderPasteMargin = atoi( Line + 13 ); else if( strnicmp( Line, ".SolderPasteRatio ", 18 ) == 0 ) m_LocalSolderPasteMarginRatio = atof( Line + 18 ); else if( strnicmp( Line, ".LocalClearance ", 16 ) == 0 ) m_LocalClearance = atoi( Line + 16 ); break; default: break; } } /* Recalculate the bounding box */ Set_Rectangle_Encadrement(); return 0; } /* Update the bounding rectangle of the module * * The bounding box includes outlines and pads, but not the fields. * The rectangle is: * for orientation 0 * coordinates relative to the module anchor. */ void MODULE::Set_Rectangle_Encadrement() { int width; int cx, cy, uxf, uyf, rayon; int xmax, ymax; int xmin, ymin; /* Initial coordinates of the module has a nonzero limit value. */ xmin = ymin = -250; xmax = ymax = 250; for( EDGE_MODULE* edge = (EDGE_MODULE*) m_Drawings.GetFirst(); edge; edge = edge->Next() ) { if( edge->Type() != TYPE_EDGE_MODULE ) continue; width = edge->m_Width / 2; switch( edge->m_Shape ) { case S_ARC: case S_CIRCLE: { cx = edge->m_Start0.x; cy = edge->m_Start0.y; // center uxf = edge->m_End0.x; uyf = edge->m_End0.y; rayon = (int) hypot( (double) ( cx - uxf ), (double) ( cy - uyf ) ); rayon += width; xmin = MIN( xmin, cx - rayon ); ymin = MIN( ymin, cy - rayon ); xmax = MAX( xmax, cx + rayon ); ymax = MAX( ymax, cy + rayon ); break; } case S_SEGMENT: xmin = MIN( xmin, edge->m_Start0.x - width ); xmin = MIN( xmin, edge->m_End0.x - width ); ymin = MIN( ymin, edge->m_Start0.y - width ); ymin = MIN( ymin, edge->m_End0.y - width ); xmax = MAX( xmax, edge->m_Start0.x + width ); xmax = MAX( xmax, edge->m_End0.x + width ); ymax = MAX( ymax, edge->m_Start0.y + width ); ymax = MAX( ymax, edge->m_End0.y + width ); break; case S_POLYGON: { std::vector polyPoints = edge->GetPolyPoints(); for( unsigned ii = 0; ii < polyPoints.size(); ii++ ) { wxPoint pt = polyPoints[ii]; xmin = MIN( xmin, (pt.x - width) ); ymin = MIN( ymin, (pt.y - width) ); xmax = MAX( xmax, (pt.x + width) ); ymax = MAX( ymax, (pt.y + width) ); } break; } } } /* Pads: find the min and max coordinates and update the bounding box. */ for( D_PAD* pad = m_Pads; pad; pad = pad->Next() ) { rayon = pad->m_ShapeMaxRadius; cx = pad->m_Pos0.x; cy = pad->m_Pos0.y; xmin = MIN( xmin, cx - rayon ); ymin = MIN( ymin, cy - rayon ); xmax = MAX( xmax, cx + rayon ); ymax = MAX( ymax, cy + rayon ); } m_BoundaryBox.m_Pos.x = xmin; m_BoundaryBox.m_Pos.y = ymin; m_BoundaryBox.SetWidth( xmax - xmin ); m_BoundaryBox.SetHeight( ymax - ymin ); } EDA_RECT MODULE::GetFootPrintRect() const { EDA_RECT area; area.m_Pos = m_Pos; area.SetEnd( m_Pos ); area.Inflate( 500 ); // Give a min size for( EDGE_MODULE* edge = (EDGE_MODULE*) m_Drawings.GetFirst(); edge; edge = edge->Next() ) { if( edge->Type() != TYPE_EDGE_MODULE ) // Should not occur continue; area.Merge( edge->GetBoundingBox() ); } for( D_PAD* pad = m_Pads; pad; pad = pad->Next() ) { area.Merge( pad->GetBoundingBox() ); } return area; } /* Equivalent to Module::Set_Rectangle_Encadrement() but in board coordinates: * Updates the module bounding box on the board * The rectangle is the rectangle with outlines and pads, but not the fields * Also updates the surface (.M_Surface) module. */ void MODULE::SetRectangleExinscrit() { m_RealBoundaryBox = GetFootPrintRect(); m_Surface = ABS( (double) m_RealBoundaryBox.GetWidth() * m_RealBoundaryBox.GetHeight() ); } /** * Function GetBoundingBox * returns the full bounding box of this Footprint, including fields * Mainly used to redraw the screen area occupied by the footprint */ EDA_RECT MODULE::GetBoundingBox() const { EDA_RECT area = GetFootPrintRect(); // Calculate extended area including text field: EDA_RECT text_area; text_area = m_Reference->GetBoundingBox(); area.Merge( text_area ); text_area = m_Value->GetBoundingBox(); area.Merge( text_area ); for( EDGE_MODULE* edge = (EDGE_MODULE*) m_Drawings.GetFirst(); edge; edge = edge->Next() ) { if( edge->Type() != TYPE_TEXTE_MODULE ) continue; text_area = ( (TEXTE_MODULE*) edge )->GetBoundingBox(); area.Merge( text_area ); } // Add the Clearance shape size: (shape around the pads when the // clearance is shown. Not optimized, but the draw cost is small // (perhaps smaller than optimization). int biggest_clearance = GetBoard()->GetBiggestClearanceValue(); area.Inflate( biggest_clearance ); return area; } /* Virtual function, from EDA_ITEM. * display module info on MsgPanel */ void MODULE::DisplayInfo( EDA_DRAW_FRAME* frame ) { int nbpad; char bufcar[512], Line[512]; bool flag = FALSE; wxString msg; BOARD* board = GetBoard(); frame->EraseMsgBox(); if( frame->m_Ident != PCB_FRAME ) flag = TRUE; frame->AppendMsgPanel( m_Reference->m_Text, m_Value->m_Text, DARKCYAN ); if( flag ) // Display last date the component was edited( useful in Module Editor) { time_t edit_time = m_LastEdit_Time; strcpy( Line, ctime( &edit_time ) ); strtok( Line, " \n\r" ); strcpy( bufcar, strtok( NULL, " \n\r" ) ); strcat( bufcar, " " ); strcat( bufcar, strtok( NULL, " \n\r" ) ); strcat( bufcar, ", " ); strtok( NULL, " \n\r" ); strcat( bufcar, strtok( NULL, " \n\r" ) ); msg = FROM_UTF8( bufcar ); frame->AppendMsgPanel( _( "Last Change" ), msg, BROWN ); } else // display time stamp in schematic { msg.Printf( wxT( "%8.8lX" ), m_TimeStamp ); frame->AppendMsgPanel( _( "Netlist path" ), m_Path, BROWN ); } frame->AppendMsgPanel( _( "Layer" ), board->GetLayerName( m_Layer ), RED ); EDA_ITEM* PtStruct = m_Pads; nbpad = 0; while( PtStruct ) { nbpad++; PtStruct = PtStruct->Next(); } msg.Printf( wxT( "%d" ), nbpad ); frame->AppendMsgPanel( _( "Pads" ), msg, BLUE ); msg = wxT( ".." ); if( IsLocked() ) msg[0] = 'L'; if( m_ModuleStatus & MODULE_is_PLACED ) msg[1] = 'P'; frame->AppendMsgPanel( _( "Stat" ), msg, MAGENTA ); msg.Printf( wxT( "%.1f" ), (float) m_Orient / 10 ); frame->AppendMsgPanel( _( "Orient" ), msg, BROWN ); frame->AppendMsgPanel( _( "Module" ), m_LibRef, BLUE ); if( m_3D_Drawings != NULL ) msg = m_3D_Drawings->m_Shape3DName; else msg = _( "No 3D shape" ); frame->AppendMsgPanel( _( "3D-Shape" ), msg, RED ); wxString doc = _( "Doc: " ) + m_Doc; wxString keyword = _( "KeyW: " ) + m_KeyWord; frame->AppendMsgPanel( doc, keyword, BLACK ); } /** * Function HitTest * tests if the given wxPoint is within the bounds of this object. * @param refPos A wxPoint to test * @return bool - true if a hit, else false */ bool MODULE::HitTest( const wxPoint& refPos ) { /* Calculation of the cursor coordinate relative to module */ wxPoint pos = refPos - m_Pos; RotatePoint( &pos, -m_Orient ); /* Check if cursor is in the rectangle. */ if( m_BoundaryBox.Contains( pos ) ) return true; return false; } /** * Function HitTest (overlaid) * tests if the given EDA_RECT intersect the bounds of this object. * @param refArea : the given EDA_RECT * @return bool - true if a hit, else false */ bool MODULE::HitTest( EDA_RECT& refArea ) { bool is_out_of_box = false; SetRectangleExinscrit(); if( m_RealBoundaryBox.m_Pos.x < refArea.GetX() ) is_out_of_box = true; if( m_RealBoundaryBox.m_Pos.y < refArea.GetY() ) is_out_of_box = true; if( m_RealBoundaryBox.GetRight() > refArea.GetRight() ) is_out_of_box = true; if( m_RealBoundaryBox.GetBottom() > refArea.GetBottom() ) is_out_of_box = true; return is_out_of_box ? false : true; } D_PAD* MODULE::FindPadByName( const wxString& aPadName ) const { wxString buf; for( D_PAD* pad = m_Pads; pad; pad = pad->Next() ) { pad->ReturnStringPadName( buf ); #if 1 if( buf.CmpNoCase( aPadName ) == 0 ) // why case insensitive? #else if( buf == aPadName ) #endif return pad; } return NULL; } // see class_module.h SEARCH_RESULT MODULE::Visit( INSPECTOR* inspector, const void* testData, const KICAD_T scanTypes[] ) { KICAD_T stype; SEARCH_RESULT result = SEARCH_CONTINUE; const KICAD_T* p = scanTypes; bool done = false; #if 0 && defined(DEBUG) std::cout << GetClass().mb_str() << ' '; #endif while( !done ) { stype = *p; switch( stype ) { case TYPE_MODULE: result = inspector->Inspect( this, testData ); // inspect me ++p; break; case TYPE_PAD: result = IterateForward( m_Pads, inspector, testData, p ); ++p; break; case TYPE_TEXTE_MODULE: result = inspector->Inspect( m_Reference, testData ); if( result == SEARCH_QUIT ) break; result = inspector->Inspect( m_Value, testData ); if( result == SEARCH_QUIT ) break; // m_Drawings can hold TYPETEXTMODULE also, so fall thru case TYPE_EDGE_MODULE: result = IterateForward( m_Drawings, inspector, testData, p ); // skip over any types handled in the above call. for( ; ; ) { switch( stype = *++p ) { case TYPE_TEXTE_MODULE: case TYPE_EDGE_MODULE: continue; default: ; } break; } break; default: done = true; break; } if( result == SEARCH_QUIT ) break; } return result; } wxString MODULE::GetSelectMenuText() const { wxString text; text << _( "Footprint" ) << wxT( " " ) << GetReference(); text << wxT( " (" ) << GetLayerName() << wxT( ")" ); return text; } #if defined(DEBUG) /** * Function Show * is used to output the object tree, currently for debugging only. * @param nestLevel An aid to prettier tree indenting, and is the level * of nesting of this object within the overall tree. * @param os The ostream& to output to. */ void MODULE::Show( int nestLevel, std::ostream& os ) { BOARD* board = GetBoard(); // for now, make it look like XML, expand on this later. NestedSpace( nestLevel, os ) << '<' << GetClass().Lower().mb_str() << " ref=\"" << m_Reference->m_Text.mb_str() << '"' << " value=\"" << m_Value->m_Text.mb_str() << '"' << " layer=\"" << board->GetLayerName( m_Layer ).mb_str() << '"' << ">\n"; NestedSpace( nestLevel + 1, os ) << "\n"; NestedSpace( nestLevel + 1, os ) << "\n"; EDA_ITEM* p; NestedSpace( nestLevel + 1, os ) << "\n"; p = m_Pads; for( ; p; p = p->Next() ) p->Show( nestLevel + 2, os ); NestedSpace( nestLevel + 1, os ) << "\n"; NestedSpace( nestLevel + 1, os ) << "\n"; p = m_Drawings; for( ; p; p = p->Next() ) p->Show( nestLevel + 2, os ); NestedSpace( nestLevel + 1, os ) << "\n"; p = m_Son; for( ; p; p = p->Next() ) { p->Show( nestLevel + 1, os ); } NestedSpace( nestLevel, os ) << "\n"; } #endif