kicad/pcbnew/gen_drill_report_files.cpp

433 lines
15 KiB
C++

/************************************************************************/
/* Functions to create drill data used to create files and report files */
/************************************************************************/
#include <fctsys.h>
#include <common.h>
#include <plot_common.h>
#include <base_struct.h>
#include <colors.h>
#include <drawtxt.h>
#include <confirm.h>
#include <kicad_string.h>
#include <macros.h>
#include <class_board.h>
#include <pcbnew.h>
#include <pcbplot.h>
#include <gendrill.h>
void GenDrillMapFile( BOARD* aPcb, FILE* aFile, const wxString& aFullFileName,
const PAGE_INFO& aSheet,
std::vector<HOLE_INFO> aHoleListBuffer,
std::vector<DRILL_TOOL> aToolListBuffer,
bool aUnit_Drill_is_Inch, int format,
const wxPoint& auxoffset )
{
int x, y;
int plotX, plotY, TextWidth;
double scale = 1.0;
int intervalle = 0, CharSize = 0;
EDA_ITEM* PtStruct;
char line[1024];
int dX, dY;
wxPoint BoardCentre;
wxPoint offset;
wxString msg;
PLOTTER* plotter = NULL;
const PCB_PLOT_PARAMS& plot_opts = aPcb->GetPlotOptions();
LOCALE_IO toggle; // use standard notation for float numbers
// Calculate dimensions and center of PCB
EDA_RECT bbbox = aPcb->ComputeBoundingBox();
dX = bbbox.GetWidth();
dY = bbbox.GetHeight();
BoardCentre = bbbox.Centre();
// Calculate the scale for the format type, scale 1 in HPGL, drawing on
// an A4 sheet in PS, + text description of symbols
switch( format )
{
case PLOT_FORMAT_GERBER:
scale = 1;
offset = auxoffset;
plotter = new GERBER_PLOTTER();
plotter->set_viewport( offset, scale, 0 );
break;
case PLOT_FORMAT_HPGL: // Scale for HPGL format.
{
offset.x = 0;
offset.y = 0;
scale = 1;
HPGL_PLOTTER* hpgl_plotter = new HPGL_PLOTTER;
plotter = hpgl_plotter;
hpgl_plotter->set_pen_number( plot_opts.m_HPGLPenNum );
hpgl_plotter->set_pen_speed( plot_opts.m_HPGLPenSpeed );
hpgl_plotter->set_pen_overlap( 0 );
plotter->SetPageSettings( aSheet );
plotter->set_viewport( offset, scale, 0 );
}
break;
case PLOT_FORMAT_POST:
{
PAGE_INFO pageA4( wxT( "A4" ) );
wxSize pageSizeIU = pageA4.GetSizeIU();
// Keep size for drill legend
double Xscale = (double) ( pageSizeIU.x * 0.8 ) / dX;
double Yscale = (double) ( pageSizeIU.y * 0.6 ) / dY;
scale = MIN( Xscale, Yscale );
offset.x = (int) ( (double) BoardCentre.x - ( (double) pageSizeIU.x / 2.0 ) / scale );
offset.y = (int) ( (double) BoardCentre.y - ( (double) pageSizeIU.y / 2.0 ) / scale );
offset.y += pageSizeIU.y / 8; // offset to legend
PS_PLOTTER* ps_plotter = new PS_PLOTTER;
plotter = ps_plotter;
ps_plotter->SetPageSettings( pageA4 );
plotter->set_viewport( offset, scale, 0 );
}
break;
case PLOT_FORMAT_DXF:
{
offset.x = 0;
offset.y = 0;
scale = 1;
DXF_PLOTTER* dxf_plotter = new DXF_PLOTTER;
plotter = dxf_plotter;
plotter->SetPageSettings( aSheet );
plotter->set_viewport( offset, scale, 0 );
}
break;
default:
wxASSERT( false );
}
plotter->set_creator( wxT( "PCBNEW" ) );
plotter->set_filename( aFullFileName );
plotter->set_default_line_width( 10 );
plotter->start_plot( aFile );
// Draw items on edge layer
for( PtStruct = aPcb->m_Drawings; PtStruct != NULL; PtStruct = PtStruct->Next() )
{
switch( PtStruct->Type() )
{
case PCB_LINE_T:
PlotDrawSegment( plotter, plot_opts, (DRAWSEGMENT*) PtStruct, EDGE_LAYER, FILLED );
break;
case PCB_TEXT_T:
PlotTextePcb( plotter, plot_opts, (TEXTE_PCB*) PtStruct, EDGE_LAYER, FILLED );
break;
case PCB_DIMENSION_T:
PlotDimension( plotter, plot_opts, (DIMENSION*) PtStruct, EDGE_LAYER, FILLED );
break;
case PCB_TARGET_T:
PlotPcbTarget( plotter, plot_opts, (PCB_TARGET*) PtStruct, EDGE_LAYER, FILLED );
break;
case PCB_MARKER_T: // do not draw
break;
default:
DisplayError( NULL, wxT( "WinEDA_DrillFrame::GenDrillMap() : Unexpected Draw Type" ) );
break;
}
}
// Set Drill Symbols width in 1/10000 mils
plotter->set_default_line_width( 10 );
plotter->set_current_line_width( -1 );
// Plot board outlines and drill map
Gen_Drill_PcbMap( aPcb, plotter, aHoleListBuffer, aToolListBuffer );
// Print a list of symbols used.
CharSize = 800; // text size in 1/10000 mils
double CharScale = 1.0 / scale; /* real scale will be CharScale
* scale_x, because the global
* plot scale is scale_x */
TextWidth = (int) ( (CharSize * CharScale) / 10 ); // Set text width (thickness)
intervalle = (int) ( CharSize * CharScale ) + TextWidth;
// Trace information.
plotX = (int) ( (double) bbbox.GetX() + 200.0 * CharScale );
plotY = bbbox.GetBottom() + intervalle;
// Plot title "Info"
wxString Text = wxT( "Drill Map:" );
plotter->text( wxPoint( plotX, plotY ), BLACK, Text, 0,
wxSize( (int) ( CharSize * CharScale ),
(int) ( CharSize * CharScale ) ),
GR_TEXT_HJUSTIFY_LEFT, GR_TEXT_VJUSTIFY_CENTER,
TextWidth, false, false );
for( unsigned ii = 0; ii < aToolListBuffer.size(); ii++ )
{
int plot_diam;
if( aToolListBuffer[ii].m_TotalCount == 0 )
continue;
plotY += intervalle;
plot_diam = (int) aToolListBuffer[ii].m_Diameter;
x = (int) ( (double) plotX - 200.0 * CharScale - (double)plot_diam / 2.0 );
y = (int) ( (double) plotY + (double) CharSize * CharScale );
plotter->marker( wxPoint( x, y ), plot_diam, ii );
// Trace the legends.
// List the diameter of each drill in the selected Drill Unit,
// and then its diameter in the other Drill Unit.
if( aUnit_Drill_is_Inch )
sprintf( line, "%2.3f\" / %2.2fmm ",
double (aToolListBuffer[ii].m_Diameter) * 0.0001,
double (aToolListBuffer[ii].m_Diameter) * 0.00254 );
else
sprintf( line, "%2.2fmm / %2.3f\" ",
double (aToolListBuffer[ii].m_Diameter) * 0.00254,
double (aToolListBuffer[ii].m_Diameter) * 0.0001 );
msg = FROM_UTF8( line );
// Now list how many holes and ovals are associated with each drill.
if( ( aToolListBuffer[ii].m_TotalCount == 1 )
&& ( aToolListBuffer[ii].m_OvalCount == 0 ) )
sprintf( line, "(1 hole)" );
else if( aToolListBuffer[ii].m_TotalCount == 1 ) // && ( aToolListBuffer[ii]m_OvalCount == 1 )
sprintf( line, "(1 slot)" );
else if( aToolListBuffer[ii].m_OvalCount == 0 )
sprintf( line, "(%d holes)", aToolListBuffer[ii].m_TotalCount );
else if( aToolListBuffer[ii].m_OvalCount == 1 )
sprintf( line, "(%d holes + 1 slot)", aToolListBuffer[ii].m_TotalCount - 1 );
else // if ( aToolListBuffer[ii]m_OvalCount > 1 )
sprintf( line, "(%d holes + %d slots)",
aToolListBuffer[ii].m_TotalCount -
aToolListBuffer[ii].m_OvalCount,
aToolListBuffer[ii].m_OvalCount );
msg += FROM_UTF8( line );
plotter->text( wxPoint( plotX, y ), BLACK,
msg,
0, wxSize( (int) ( CharSize * CharScale ), (int) ( CharSize * CharScale ) ),
GR_TEXT_HJUSTIFY_LEFT, GR_TEXT_VJUSTIFY_CENTER,
TextWidth, false, false );
intervalle = (int) ( CharSize * CharScale ) + TextWidth;
intervalle = (int) ( intervalle * 1.2 );
if( intervalle < (plot_diam + 200 + TextWidth) )
intervalle = plot_diam + 200 + TextWidth;
}
plotter->end_plot();
delete plotter;
}
/** Creates the drill map aFile in HPGL or POSTSCRIPT format
* @param aPcb = the BOARD
* @param aPlotter = a PLOTTER instance (HPGL or POSTSCRIPT plotter).
* @param aHoleListBuffer = std::vector<HOLE_INFO> list of holes descriptors
* @param aToolListBuffer = std::vector<DRILL_TOOL> drill list buffer
*/
void Gen_Drill_PcbMap( BOARD* aPcb, PLOTTER* aPlotter,
std::vector<HOLE_INFO>& aHoleListBuffer,
std::vector<DRILL_TOOL>& aToolListBuffer )
{
wxPoint pos;
// create the drill list
if( aToolListBuffer.size() > 13 )
{
DisplayInfoMessage( NULL,
_( " Drill map: Too many diameter values to draw to draw one symbol per drill value (max 13)\nPlot uses circle shape for some drill values" ),
10 );
}
// Plot the drill map:
for( unsigned ii = 0; ii < aHoleListBuffer.size(); ii++ )
{
pos = aHoleListBuffer[ii].m_Hole_Pos;
/* Always plot the drill symbol (for slots identifies the needed
* cutter!) */
aPlotter->marker( pos, aHoleListBuffer[ii].m_Hole_Diameter,
aHoleListBuffer[ii].m_Tool_Reference - 1 );
if( aHoleListBuffer[ii].m_Hole_Shape != 0 )
{
wxSize oblong_size;
oblong_size = aHoleListBuffer[ii].m_Hole_Size;
aPlotter->flash_pad_oval( pos, oblong_size,
aHoleListBuffer[ii].m_Hole_Orient, LINE );
}
}
}
/*
* Create a list of drill values and drill count
*/
void GenDrillReportFile( FILE* aFile, BOARD* aPcb,
const wxString& aBoardFilename,
bool aUnit_Drill_is_Inch,
std::vector<HOLE_INFO>& aHoleListBuffer,
std::vector<DRILL_TOOL>& aToolListBuffer )
{
unsigned TotalHoleCount;
char line[1024];
int layer1 = LAYER_N_BACK;
int layer2 = LAYER_N_FRONT;
bool gen_through_holes = true;
bool gen_NPTH_holes = false;
fprintf( aFile, "Drill report for %s\n", TO_UTF8( aBoardFilename ) );
fprintf( aFile, "Created on %s\n", TO_UTF8( DateAndTime() ) );
// List which Drill Unit option had been selected for the associated
// drill aFile.
if( aUnit_Drill_is_Inch )
fputs( "Selected Drill Unit: Imperial (\")\n\n", aFile );
else
fputs( "Selected Drill Unit: Metric (mm)\n\n", aFile );
/* build hole lists:
* 1 - through holes
* 2 - for partial holes only: by layer pair
* 3 - Not Plated through holes
*/
for( ; ; )
{
Build_Holes_List( aPcb,
aHoleListBuffer,
aToolListBuffer,
layer1,
layer2,
gen_through_holes ? false : true, gen_NPTH_holes );
TotalHoleCount = 0;
if( gen_NPTH_holes )
{
sprintf( line, "Drill report for Not Plated through holes :\n" );
}
else if( gen_through_holes )
{
sprintf( line, "Drill report for through holes :\n" );
}
else
{
if( layer1 == LAYER_N_BACK ) // First partial hole list
{
sprintf( line, "Drill report for buried and blind vias :\n\n" );
fputs( line, aFile );
}
sprintf( line, "Drill report for holes from layer %s to layer %s\n",
TO_UTF8( aPcb->GetLayerName( layer1 ) ),
TO_UTF8( aPcb->GetLayerName( layer2 ) ) );
}
fputs( line, aFile );
for( unsigned ii = 0; ii < aToolListBuffer.size(); ii++ )
{
// List the tool number assigned to each drill,
// then its diameter in the selected Drill Unit,
// and then its diameter in the other Drill Unit.
if( aUnit_Drill_is_Inch )
sprintf( line, "T%d %2.3f\" %2.2fmm ",
ii + 1,
double (aToolListBuffer[ii].m_Diameter) * 0.0001,
double (aToolListBuffer[ii].m_Diameter) * 0.00254 );
else
sprintf( line, "T%d %2.2fmm %2.3f\" ",
ii + 1,
double (aToolListBuffer[ii].m_Diameter) * 0.00254,
double (aToolListBuffer[ii].m_Diameter) * 0.0001 );
fputs( line, aFile );
// Now list how many holes and ovals are associated with each drill.
if( ( aToolListBuffer[ii].m_TotalCount == 1 )
&& ( aToolListBuffer[ii].m_OvalCount == 0 ) )
sprintf( line, "(1 hole)\n" );
else if( aToolListBuffer[ii].m_TotalCount == 1 )
sprintf( line, "(1 hole) (with 1 oblong)\n" );
else if( aToolListBuffer[ii].m_OvalCount == 0 )
sprintf( line, "(%d holes)\n", aToolListBuffer[ii].m_TotalCount );
else if( aToolListBuffer[ii].m_OvalCount == 1 )
sprintf( line, "(%d holes) (with 1 oblong)\n", aToolListBuffer[ii].m_TotalCount );
else // if ( buffer[ii]m_OvalCount > 1 )
sprintf( line, "(%d holes) (with %d oblongs)\n",
aToolListBuffer[ii].m_TotalCount,
aToolListBuffer[ii].m_OvalCount );
fputs( line, aFile );
TotalHoleCount += aToolListBuffer[ii].m_TotalCount;
}
if( gen_NPTH_holes )
sprintf( line, "\ntotal Not Plated holes count %d\n\n\n", TotalHoleCount );
else
sprintf( line, "\ntotal plated holes count %d\n\n\n", TotalHoleCount );
fputs( line, aFile );
if( gen_NPTH_holes )
{
break;
}
else
{
if( aPcb->GetCopperLayerCount() <= 2 )
{
gen_NPTH_holes = true;
continue;
}
if( gen_through_holes )
{
layer2 = layer1 + 1;
}
else
{
if( layer2 >= LAYER_N_FRONT ) // no more layer pair to consider
{
gen_NPTH_holes = true;
continue;
}
layer1++; layer2++; // use next layer pair
if( layer2 == aPcb->GetCopperLayerCount() - 1 )
layer2 = LAYER_N_FRONT; // the last layer is always the
// component layer
}
gen_through_holes = false;
}
}
fclose( aFile );
}