/* * This program source code file is part of KiCad, a free EDA CAD application. * * Copyright (C) 1992-2017 Jean_Pierre Charras * Copyright (C) 1992-2022 KiCad Developers, see AUTHORS.txt for contributors. * * 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 */ #include #include #include #include #include #include #include #include #include #include // for KiROUND #include #include #include #include #include #include /* Conversion utilities - these will be used often in there... */ inline double diameter_in_inches( double ius ) { return ius * 0.001 / IU_PER_MILS; } inline double diameter_in_mm( double ius ) { return ius / IU_PER_MM; } // return a pen size to plot markers and having a readable shape inline int getMarkerBestPenSize( int aMarkerDiameter ) { return aMarkerDiameter / 10; } bool GENDRILL_WRITER_BASE::genDrillMapFile( const wxString& aFullFileName, PLOT_FORMAT aFormat ) { // Remark: // Hole list must be created before calling this function, by buildHolesList(), // for the right holes set (PTH, NPTH, buried/blind vias ...) double scale = 1.0; VECTOR2I offset = GetOffset(); PLOTTER* plotter = nullptr; PAGE_INFO dummy( PAGE_INFO::A4, false ); int bottom_limit = 0; // Y coord limit of page. 0 mean do not use PCB_PLOT_PARAMS plot_opts; // starts plotting with default options LOCALE_IO toggle; // use standard C notation for float numbers const PAGE_INFO& page_info = m_pageInfo ? *m_pageInfo : dummy; // Calculate dimensions and center of PCB. The Edge_Cuts layer must be visible // to calculate the board edges bounding box LSET visibleLayers = m_pcb->GetVisibleLayers(); m_pcb->SetVisibleLayers( visibleLayers | LSET( Edge_Cuts ) ); EDA_RECT bbbox = m_pcb->GetBoardEdgesBoundingBox(); m_pcb->SetVisibleLayers( visibleLayers ); // Some formats cannot be used to generate a document like the map files // Currently HPGL (old format not very used) if( aFormat == PLOT_FORMAT::HPGL ) aFormat = PLOT_FORMAT::PDF; // Calculate the scale for the format type, scale 1 in HPGL, drawing on // an A4 sheet in PS, + text description of symbols switch( aFormat ) { case PLOT_FORMAT::GERBER: plotter = new GERBER_PLOTTER(); plotter->SetViewport( offset, IU_PER_MILS / 10, scale, false ); plotter->SetGerberCoordinatesFormat( 5 ); // format x.5 unit = mm break; default: wxASSERT( false ); KI_FALLTHROUGH; case PLOT_FORMAT::PDF: case PLOT_FORMAT::POST: case PLOT_FORMAT::SVG: { PAGE_INFO pageA4( wxT( "A4" ) ); wxSize pageSizeIU = pageA4.GetSizeIU( IU_PER_MILS ); // Reserve a 10 mm margin around the page. int margin = Millimeter2iu( 10 ); // Calculate a scaling factor to print the board on the sheet double Xscale = double( pageSizeIU.x - ( 2 * margin ) ) / bbbox.GetWidth(); // We should print the list of drill sizes, so reserve room for it // 60% height for board 40% height for list int ypagesize_for_board = KiROUND( pageSizeIU.y * 0.6 ); double Yscale = double( ypagesize_for_board - margin ) / bbbox.GetHeight(); scale = std::min( Xscale, Yscale ); // Experience shows the scale should not to large, because texts // create problem (can be to big or too small). // So the scale is clipped at 3.0; scale = std::min( scale, 3.0 ); offset.x = KiROUND( double( bbbox.Centre().x ) - ( pageSizeIU.x / 2.0 ) / scale ); offset.y = KiROUND( double( bbbox.Centre().y ) - ( ypagesize_for_board / 2.0 ) / scale ); // bottom_limit is used to plot the legend (drill diameters) // texts are scaled differently for scale > 1.0 and <= 1.0 // so the limit is scaled differently. bottom_limit = ( pageSizeIU.y - margin ) / std::min( scale, 1.0 ); if( aFormat == PLOT_FORMAT::SVG ) plotter = new SVG_PLOTTER; else if( aFormat == PLOT_FORMAT::PDF ) plotter = new PDF_PLOTTER; else plotter = new PS_PLOTTER; plotter->SetPageSettings( pageA4 ); plotter->SetViewport( offset, IU_PER_MILS / 10, scale, false ); break; } case PLOT_FORMAT::DXF: { DXF_PLOTTER* dxf_plotter = new DXF_PLOTTER; if( m_unitsMetric ) dxf_plotter->SetUnits( DXF_UNITS::MILLIMETERS ); else dxf_plotter->SetUnits( DXF_UNITS::INCHES ); plotter = dxf_plotter; plotter->SetPageSettings( page_info ); plotter->SetViewport( offset, IU_PER_MILS / 10, scale, false ); break; } } plotter->SetCreator( wxT( "PCBNEW" ) ); plotter->SetColorMode( false ); KIGFX::PCB_RENDER_SETTINGS renderSettings; renderSettings.SetDefaultPenWidth( Millimeter2iu( 0.2 ) ); plotter->SetRenderSettings( &renderSettings ); if( !plotter->OpenFile( aFullFileName ) ) { delete plotter; return false; } plotter->ClearHeaderLinesList(); // For the Gerber X2 format we need to set the "FileFunction" to Drillmap // and set a few other options. if( plotter->GetPlotterType() == PLOT_FORMAT::GERBER ) { GERBER_PLOTTER* gbrplotter = static_cast ( plotter ); gbrplotter->DisableApertMacros( false ); gbrplotter->UseX2format( true ); // Mandatory gbrplotter->UseX2NetAttributes( false ); // net attributes have no meaning here // Attributes are added using X2 format AddGerberX2Header( gbrplotter, m_pcb, false ); wxString text; // Add the TF.FileFunction text = "%TF.FileFunction,Drillmap*%"; gbrplotter->AddLineToHeader( text ); // Add the TF.FilePolarity text = wxT( "%TF.FilePolarity,Positive*%" ); gbrplotter->AddLineToHeader( text ); } plotter->StartPlot(); // Draw items on edge layer. // Not all, only items useful for drill map, i.e. board outlines. BRDITEMS_PLOTTER itemplotter( plotter, m_pcb, plot_opts ); // Use attributes of a drawing layer (we are not really draw the Edge.Cuts layer) itemplotter.SetLayerSet( Dwgs_User ); for( BOARD_ITEM* item : m_pcb->Drawings() ) { if( item->GetLayer() != Edge_Cuts ) continue; switch( item->Type() ) { case PCB_SHAPE_T: { PCB_SHAPE dummy_shape( *static_cast( item ) ); dummy_shape.SetLayer( Dwgs_User ); itemplotter.PlotPcbShape( &dummy_shape ); } break; default: break; } } int plotX, plotY, TextWidth; int intervalle = 0; char line[1024]; wxString msg; int textmarginaftersymbol = Millimeter2iu( 2 ); // Set Drill Symbols width plotter->SetCurrentLineWidth( -1 ); // Plot board outlines and drill map plotDrillMarks( plotter ); // Print a list of symbols used. int charSize = Millimeter2iu( 2 ); // text size in IUs // real char scale will be 1/scale, because the global plot scale is scale // for scale < 1.0 ( plot bigger actual size) // Therefore charScale = 1.0 / scale keep the initial charSize // (for scale < 1 we use the global scaling factor: the board must be plotted // smaller than the actual size) double charScale = std::min( 1.0, 1.0 / scale ); TextWidth = KiROUND( ( charSize * charScale ) / 10.0 ); // Set text width (thickness) intervalle = KiROUND( charSize * charScale ) + TextWidth; // Trace information. plotX = KiROUND( bbbox.GetX() + textmarginaftersymbol * charScale ); plotY = bbbox.GetBottom() + intervalle; // Plot title "Info" wxString Text = wxT( "Drill Map:" ); plotter->Text( VECTOR2I( plotX, plotY ), COLOR4D::UNSPECIFIED, Text, ANGLE_HORIZONTAL, wxSize( KiROUND( charSize * charScale ), KiROUND( charSize * charScale ) ), GR_TEXT_H_ALIGN_LEFT, GR_TEXT_V_ALIGN_CENTER, TextWidth, false, false, false, nullptr /* stroke font */ ); // For some formats (PS, PDF SVG) we plot the drill size list on more than one column // because the list must be contained inside the printed page // (others formats do not have a defined page size) int max_line_len = 0; // The max line len in iu of the currently plotted column for( unsigned ii = 0; ii < m_toolListBuffer.size(); ii++ ) { DRILL_TOOL& tool = m_toolListBuffer[ii]; if( tool.m_TotalCount == 0 ) continue; plotY += intervalle; // Ensure there are room to plot the line if( bottom_limit && ( plotY+intervalle > bottom_limit ) ) { plotY = bbbox.GetBottom() + intervalle; plotX += max_line_len + Millimeter2iu( 10 );//column_width; max_line_len = 0; } int plot_diam = KiROUND( tool.m_Diameter ); // For markers plotted with the comment, keep marker size <= text height plot_diam = std::min( plot_diam, KiROUND( charSize * charScale ) ); int x = KiROUND( plotX - textmarginaftersymbol * charScale - plot_diam / 2.0 ); int y = KiROUND( plotY + charSize * charScale ); plotter->SetCurrentLineWidth( getMarkerBestPenSize( plot_diam ) ); plotter->Marker( VECTOR2I( x, y ), plot_diam, ii ); plotter->SetCurrentLineWidth( -1 ); // List the diameter of each drill in mm and inches. sprintf( line, "%3.3fmm / %2.4f\" ", diameter_in_mm( tool.m_Diameter ), diameter_in_inches( tool.m_Diameter ) ); msg = FROM_UTF8( line ); // Now list how many holes and ovals are associated with each drill. if( ( tool.m_TotalCount == 1 ) && ( tool.m_OvalCount == 0 ) ) sprintf( line, "(1 hole)" ); else if( tool.m_TotalCount == 1 ) // && ( toolm_OvalCount == 1 ) sprintf( line, "(1 slot)" ); else if( tool.m_OvalCount == 0 ) sprintf( line, "(%d holes)", tool.m_TotalCount ); else if( tool.m_OvalCount == 1 ) sprintf( line, "(%d holes + 1 slot)", tool.m_TotalCount - 1 ); else // if ( toolm_OvalCount > 1 ) sprintf( line, "(%d holes + %d slots)", tool.m_TotalCount - tool.m_OvalCount, tool.m_OvalCount ); msg += FROM_UTF8( line ); if( tool.m_Hole_NotPlated ) msg += wxT( " (not plated)" ); plotter->Text( VECTOR2I( plotX, y ), COLOR4D::UNSPECIFIED, msg, ANGLE_HORIZONTAL, VECTOR2I( KiROUND( charSize * charScale ), KiROUND( charSize * charScale ) ), GR_TEXT_H_ALIGN_LEFT, GR_TEXT_V_ALIGN_CENTER, TextWidth, false, false, false, nullptr /* stroke font */ ); intervalle = KiROUND( ( ( charSize * charScale ) + TextWidth ) * 1.2 ); if( intervalle < ( plot_diam + ( 1 * IU_PER_MM / scale ) + TextWidth ) ) intervalle = plot_diam + ( 1 * IU_PER_MM / scale ) + TextWidth; // Evaluate the text horizontal size, to know the maximal column size // This is a rough value, but ok to create a new column to plot next texts int text_len = msg.Len() * ( ( charSize * charScale ) + TextWidth ); max_line_len = std::max( max_line_len, text_len + plot_diam ); } plotter->EndPlot(); delete plotter; return true; } bool GENDRILL_WRITER_BASE::GenDrillReportFile( const wxString& aFullFileName ) { FILE_OUTPUTFORMATTER out( aFullFileName ); static const char separator[] = " =============================================================\n"; wxASSERT( m_pcb ); unsigned totalHoleCount; wxFileName brdFilename( m_pcb->GetFileName() ); std::vector hole_sets = getUniqueLayerPairs(); out.Print( 0, "Drill report for %s\n", TO_UTF8( brdFilename.GetFullName() ) ); out.Print( 0, "Created on %s\n\n", TO_UTF8( DateAndTime() ) ); // Output the cu layer stackup, so layer name references make sense. out.Print( 0, "Copper Layer Stackup:\n" ); out.Print( 0, separator ); LSET cu = m_pcb->GetEnabledLayers() & LSET::AllCuMask(); int conventional_layer_num = 1; for( LSEQ seq = cu.Seq(); seq; ++seq, ++conventional_layer_num ) { out.Print( 0, " L%-2d: %-25s %s\n", conventional_layer_num, TO_UTF8( m_pcb->GetLayerName( *seq ) ), layerName( *seq ).c_str() ); // generic layer name } out.Print( 0, "\n\n" ); /* output hole lists: * 1 - through holes * 2 - for partial holes only: by layer starting and ending pair * 3 - Non Plated through holes */ bool buildNPTHlist = false; // First pass: build PTH list only // in this loop are plated only: for( unsigned pair_ndx = 0; pair_ndx < hole_sets.size(); ++pair_ndx ) { DRILL_LAYER_PAIR pair = hole_sets[pair_ndx]; buildHolesList( pair, buildNPTHlist ); if( pair == DRILL_LAYER_PAIR( F_Cu, B_Cu ) ) { out.Print( 0, "Drill file '%s' contains\n", TO_UTF8( getDrillFileName( pair, false, m_merge_PTH_NPTH ) ) ); out.Print( 0, " plated through holes:\n" ); out.Print( 0, separator ); totalHoleCount = printToolSummary( out, false ); out.Print( 0, " Total plated holes count %u\n", totalHoleCount ); } else // blind/buried { out.Print( 0, "Drill file '%s' contains\n", TO_UTF8( getDrillFileName( pair, false, m_merge_PTH_NPTH ) ) ); out.Print( 0, " holes connecting layer pair: '%s and %s' (%s vias):\n", TO_UTF8( m_pcb->GetLayerName( ToLAYER_ID( pair.first ) ) ), TO_UTF8( m_pcb->GetLayerName( ToLAYER_ID( pair.second ) ) ), pair.first == F_Cu || pair.second == B_Cu ? "blind" : "buried" ); out.Print( 0, separator ); totalHoleCount = printToolSummary( out, false ); out.Print( 0, " Total plated holes count %u\n", totalHoleCount ); } out.Print( 0, "\n\n" ); } // NPTHoles. Generate the full list (pads+vias) if PTH and NPTH are merged, // or only the NPTH list (which never has vias) if( !m_merge_PTH_NPTH ) buildNPTHlist = true; buildHolesList( DRILL_LAYER_PAIR( F_Cu, B_Cu ), buildNPTHlist ); // nothing wrong with an empty NPTH file in report. if( m_merge_PTH_NPTH ) out.Print( 0, "Not plated through holes are merged with plated holes\n" ); else out.Print( 0, "Drill file '%s' contains\n", TO_UTF8( getDrillFileName( DRILL_LAYER_PAIR( F_Cu, B_Cu ), true, m_merge_PTH_NPTH ) ) ); out.Print( 0, " unplated through holes:\n" ); out.Print( 0, separator ); totalHoleCount = printToolSummary( out, true ); out.Print( 0, " Total unplated holes count %u\n", totalHoleCount ); return true; } bool GENDRILL_WRITER_BASE::plotDrillMarks( PLOTTER* aPlotter ) { // Plot the drill map: VECTOR2I pos; for( unsigned ii = 0; ii < m_holeListBuffer.size(); ii++ ) { const HOLE_INFO& hole = m_holeListBuffer[ii]; pos = hole.m_Hole_Pos; // Gives a good line thickness to have a good marker shape: aPlotter->SetCurrentLineWidth( getMarkerBestPenSize( hole.m_Hole_Diameter ) ); // Always plot the drill symbol (for slots identifies the needed cutter! aPlotter->Marker( pos, hole.m_Hole_Diameter, hole.m_Tool_Reference - 1 ); if( hole.m_Hole_Shape != 0 ) aPlotter->FlashPadOval( pos, hole.m_Hole_Size, hole.m_Hole_Orient, SKETCH, nullptr ); } aPlotter->SetCurrentLineWidth( -1 ); return true; } unsigned GENDRILL_WRITER_BASE::printToolSummary( OUTPUTFORMATTER& out, bool aSummaryNPTH ) const { unsigned totalHoleCount = 0; for( unsigned ii = 0; ii < m_toolListBuffer.size(); ii++ ) { const DRILL_TOOL& tool = m_toolListBuffer[ii]; if( aSummaryNPTH && !tool.m_Hole_NotPlated ) continue; if( !aSummaryNPTH && tool.m_Hole_NotPlated ) continue; // List the tool number assigned to each drill in mm then in inches. int tool_number = ii+1; out.Print( 0, " T%d %2.3fmm %2.4f\" ", tool_number, diameter_in_mm( tool.m_Diameter ), diameter_in_inches( tool.m_Diameter ) ); // Now list how many holes and ovals are associated with each drill. if( ( tool.m_TotalCount == 1 ) && ( tool.m_OvalCount == 0 ) ) out.Print( 0, "(1 hole)\n" ); else if( tool.m_TotalCount == 1 ) out.Print( 0, "(1 hole) (with 1 slot)\n" ); else if( tool.m_OvalCount == 0 ) out.Print( 0, "(%d holes)\n", tool.m_TotalCount ); else if( tool.m_OvalCount == 1 ) out.Print( 0, "(%d holes) (with 1 slot)\n", tool.m_TotalCount ); else // tool.m_OvalCount > 1 out.Print( 0, "(%d holes) (with %d slots)\n", tool.m_TotalCount, tool.m_OvalCount ); totalHoleCount += tool.m_TotalCount; } out.Print( 0, "\n" ); return totalHoleCount; }