kicad/pcbnew/gpcb_exchange.cpp

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/****************************************************/
/* class_module.cpp : fonctions de la classe MODULE */
/****************************************************/
#include "fctsys.h"
#include "wxstruct.h"
#include "common.h"
#include "pcbnew.h"
#include "trigo.h"
/* read parameters from a line, and return all params in a wxArrayString
* each param is in one wxString, and double quotes removed if exists
*/
static void Extract_Parameters( wxArrayString& param_list, char* text );
static bool TestFlags( const wxString& flg_string, long flg_mask, const wxChar* flg_name );
/**************************************************************/
bool MODULE::Read_GPCB_Descr( const wxString& CmpFullFileName )
/**************************************************************/
/**
* Function Read_GPCB_Descr
* Read a footprint description in GPCB (Newlib) format
* @param CmpFullFileName = Full file name (there is one footprint per file.
* this is also the footprint name
* @return bool - true if success reading else false.
*/
/* a sample is
*
* Element["" "" "" "" 29000 44000 0 0 0 100 ""]
* (
* Pad[-5000 0 -4000 0 4999 0 4999 "" "1" "square"]
* Pad[4000 0 5000 0 4999 0 4999 "" "2" "square,edge2"]
* ElementLine [8000 3000 1000 3000 199]
* ElementLine [8000 -3000 8000 3000 199]
* ElementLine [-8000 3000 -1000 3000 199]
* ElementLine [-8000 -3000 -1000 -3000 199]
* ElementLine [8000 -3000 1000 -3000 199]
* ElementLine [-8000 -3000 -8000 3000 199]
* )
*
* Format
* Element [SFlags "Desc" "Name" "Value" MX MY TX TY TDir TScale TSFlags]
* Element (NFlags "Desc" "Name" "Value" MX MY TX TY TDir TScale TNFlags)
* Element (NFlags "Desc" "Name" "Value" TX TY TDir TScale TNFlags)
* Element (NFlags "Desc" "Name" TX TY TDir TScale TNFlags)
* Element ("Desc" "Name" TX TY TDir TScale TNFlags)
* (
* . . . contents . . . *
* )
* With:
* SFlags Symbolic or numeric flags, for the element as a whole.
* NFlags Numeric flags, for the element as a whole.
* Desc The description of the element. This is one of the three strings which can be
* displayed on the screen.
* Name The name of the element, usually the reference designator.
* Value The value of the element.
* MX MY The location of the element<EFBFBD>s mark. This is the reference point for placing the element and its pins and pads.
* TX TY The upper left corner of the text (one of the three strings).
* TDir The relative direction of the text. 0 means left to right for an unrotated element, 1 means up, 2 left, 3 down.
* TScale Size of the text, as a percentage of the <EFBFBD>default<EFBFBD> size of of the font (the default font is about 40 mils high). Default is 100 (40 mils).
* TSFlags Symbolic or numeric flags, for the text.
* TNFlags Numeric flags, for the text.
*
* Elements may contain pins, pads, element
*
* ElementLine [X1 Y1 X2 Y2 Thickness]
* ElementLine (X1 Y1 X2 Y2 Thickness)
*
* ElementArc [X Y Width Height StartAngle DeltaAngle Thickness]
* ElementArc (X Y Width Height StartAngle DeltaAngle Thickness)
* (rotation in clockwise)
* Pad [rX1 rY1 rX2 rY2 Thickness Clearance Mask "Name" "Number" SFlags]
* Pad (rX1 rY1 rX2 rY2 Thickness Clearance Mask "Name" "Number" NFlags)
* Pad (aX1 aY1 aX2 aY2 Thickness "Name" "Number" NFlags)
* Pad (aX1 aY1 aX2 aY2 Thickness "Name" NFlags)
*
* Pin [rX rY Thickness Clearance Mask Drill "Name" "Number" SFlags]
* Pin (rX rY Thickness Clearance Mask Drill "Name" "Number" NFlags)
* Pin (aX aY Thickness Drill "Name" "Number" NFlags)
* Pin (aX aY Thickness Drill "Name" NFlags)
* Pin (aX aY Thickness "Name" NFlags)
*
* Object Flags :
*
* Note that object flags can be given numerically (like 0x0147) or symbolically (like
* "found,showname,square". Some numeric values are reused for different object types.
* The table below lists the numeric value followed by the symbolic name.
* 0x0001 pin
* If set, this object is a pin. This flag is for internal use only.
* 0x0002 via
* Likewise, for vias.
* 0x0004 found
* If set, this object has been found by FindConnection().
* 0x0008 hole
* For pins and vias, this flag means that the pin or via is a hole without a copper
* annulus.
* 0x0010 rat
* If set for a line, indicates that this line is a rat line instead of a copper trace.
* 0x0010 pininpoly
* For pins and pads, this flag is used internally to indicate that the pin or pad
* overlaps a polygon on some layer.
* 0x0010 clearpoly
* For polygons, this flag means that pins and vias will normally clear these polygons
* (thus, thermals are required for electrical connection). When clear, polygons
* will solidly connect to pins and vias.
* 0x0010 hidename
* For elements, when set the name of the element is hidden.
* 0x0020 showname
* For elements, when set the names of pins are shown.
* 0x0020 clearline
* For lines and arcs, the line/arc will clear polygons instead of connecting to
* them.
* 0x0020 fullpoly
* For polygons, the full polygon is drawn (i.e. all parts instead of only the biggest
* one).
* 0x0040 selected
* Set when the object is selected.
* 0x0080 onsolder
* For elements and pads, indicates that they are on the solder side
* 0x0080 auto
* For lines and vias, indicates that these were created by the autorouter.
* 0x0100 square
* For pins and pads, indicates a square (vs round) pin/pad.
* 0x0200 rubberend
* For lines, used internally for rubber band moves.
* 0x0200 warn
* For pins, vias, and pads, set to indicate a warning.
* 0x0400 usetherm
* Obsolete, indicates that pins/vias should be drawn with thermal fingers.
* 0x0400 Obsolete, old files used this to indicate lines drawn on silk.
* 0x0800 octagon
* Draw pins and vias as octagons.
* 0x1000 drc
* Set for objects that fail DRC.
* 0x2000 lock
* Set for locked objects.
* 0x4000 edge2
* For pads, indicates that the second point is closer to the edge. For pins, indicates
* that the pin is closer to a horizontal edge and thus pinout text should be vertical.
* 0x8000 marker
* Marker used internally to avoid revisiting an object.
* 0x10000 nopaste
* For pads, set to prevent a solderpaste stencil opening for the pad. Primarily
* used for pads used as fiducials.
*/
{
#define TEXT_DEFAULT_SIZE 400
#define OLD_GPCB_UNIT_CONV 10
#define NEW_GPCB_UNIT_CONV 0.1
FILE* cmpfile;
double conv_unit = NEW_GPCB_UNIT_CONV; // GPCB unit = 0.01 mils and pcbnew 0.1
// Old version unit = 1 mil, so conv_unit is 10 or 0.1
bool success = true;
char Line[1024];
int NbLine = 0;
long ibuf[100];
EDGE_MODULE* DrawSegm, * LastModStruct = NULL;
D_PAD* LastPad = NULL, * Pad;
wxArrayString params;
int iprmcnt, icnt_max, iflgidx;
if( ( cmpfile = wxFopen( CmpFullFileName, wxT( "rt" ) ) ) == NULL )
return false;
GetLine( cmpfile, Line, &NbLine );
params.Clear();
Extract_Parameters( params, Line );
iprmcnt = 0;
icnt_max = params.GetCount();
if( params[iprmcnt].CmpNoCase( wxT( "Element" ) ) != 0 )
{
fclose( cmpfile );
return false;
}
// Test symbol after "Element": if [ units = 0.01 mils, and if ( units = 1 mil
iprmcnt++;
if( params[iprmcnt] == wxT( "(" ) )
conv_unit = OLD_GPCB_UNIT_CONV;
/* Analyse first line :
* Element [element_flags, description, pcb-name, value, mark_x, mark_y, text_x, text_y,
* text_direction, text_scale, text_flags]
*/
// Read flags (unused)
iprmcnt++;
// Read description
iprmcnt++;
m_Doc = params[iprmcnt];
2008-03-12 11:49:16 +00:00
// Read pcb-name (reference )
iprmcnt++;
2008-03-12 11:49:16 +00:00
m_Reference->m_Text = params[iprmcnt];
// Read value
iprmcnt++;
m_Value->m_Text = params[iprmcnt];
// Read other infos
2008-03-12 11:49:16 +00:00
iprmcnt++;
for( int ii = 0; ii < 6; ii++ )
{
if( iprmcnt < icnt_max )
{
success = false;
ibuf[ii] = 0;
}
else
params[iprmcnt].ToLong( &ibuf[ii] );
iprmcnt++;
}
m_Reference->m_Pos.x = (int) round( ibuf[2] * conv_unit );
m_Reference->m_Pos.y = (int) round( ibuf[3] * conv_unit );;
m_Reference->m_Orient = ibuf[4] * 900;
// Calculate size: default is 40 mils (400 pcb units)
// real size is: default * ibuf[5] / 100 (size in gpcb is given in percent of defalut size
ibuf[5] *= TEXT_DEFAULT_SIZE; ibuf[5] /= 100;
m_Reference->m_Size.x = m_Reference->m_Size.y = max( 20, ibuf[5] );
m_Reference->m_Width = m_Reference->m_Size.x / 10;
m_Value->m_Orient = m_Reference->m_Orient;
m_Value->m_Size = m_Reference->m_Size;
m_Value->m_Width = m_Reference->m_Width;
while( GetLine( cmpfile, Line, &NbLine, sizeof(Line) - 1 ) != NULL )
{
params.Clear();
Extract_Parameters( params, Line );
if( params.GetCount() > 3 ) // Test units value for a string line param (more than 3 params : ident [ xx ] )
{
if( params[1] == wxT( "(" ) )
conv_unit = OLD_GPCB_UNIT_CONV;
else
conv_unit = NEW_GPCB_UNIT_CONV;
}
if( params[0].CmpNoCase( wxT( "ElementLine" ) ) == 0 ) // line descr
{ // Format: ElementLine [X1 Y1 X2 Y2 Thickness]
DrawSegm = new EDGE_MODULE( this );
DrawSegm->SetLayer( SILKSCREEN_N_CMP );
DrawSegm->m_Shape = S_SEGMENT;
if( LastModStruct == NULL )
{
DrawSegm->Pback = this;
m_Drawings = DrawSegm;
}
else
{
DrawSegm->Pback = LastModStruct;
LastModStruct->Pnext = DrawSegm;
}
int* list[5] = {
&DrawSegm->m_Start0.x, &DrawSegm->m_Start0.y,
&DrawSegm->m_End0.x, &DrawSegm->m_End0.y,
&DrawSegm->m_Width
};
for( unsigned ii = 0; ii < 5; ii++ )
{
long dim;
if( ii < (params.GetCount() - 2) )
{
if( params[ii + 2].ToLong( &dim ) )
*list[ii] = (int) round( dim * conv_unit );
}
}
DrawSegm->SetDrawCoord();
LastModStruct = DrawSegm;
continue;
}
if( params[0].CmpNoCase( wxT( "ElementArc" ) ) == 0 ) // Arc descr
{ // format: ElementArc [X Y Width Height StartAngle DeltaAngle Thickness]
// pcbnew does know ellipse so we must have Width = Height
DrawSegm = new EDGE_MODULE( this );
DrawSegm->SetLayer( SILKSCREEN_N_CMP );
DrawSegm->m_Shape = S_ARC;
if( LastModStruct == NULL )
{
DrawSegm->Pback = this;
m_Drawings = DrawSegm;
}
else
{
DrawSegm->Pback = LastModStruct;
LastModStruct->Pnext = DrawSegm;
}
for( unsigned ii = 0; ii < 7; ii++ )
{
long dim;
if( ii < (params.GetCount() - 2) )
{
if( params[ii + 2].ToLong( &dim ) )
ibuf[ii] = dim;
else
ibuf[ii] = 0;
}
else
ibuf[ii] = 0;
}
int rayon = (ibuf[2] + ibuf[3]) / 4; // for and arc: ibuf[3] = ibuf[4]. pcbnew does not know ellipses
wxPoint centre;
centre.x = (int) round( ibuf[0] * conv_unit );
centre.y = (int) round( ibuf[1] * conv_unit );
DrawSegm->m_Start0 = centre;
int start_angle = ibuf[4] * 10; // Pcbnew uses 0.1 degrees as units
start_angle -= 1800; // Use normal X axis as reference
DrawSegm->m_Angle = ibuf[5] * 10; // Angle value is clockwise in gpcb and pcbnew
DrawSegm->m_End0.x = (int) round( rayon * conv_unit );
DrawSegm->m_End0.y = 0;
RotatePoint( &DrawSegm->m_End0, -start_angle ); // Calculate start point coordinate of arc
DrawSegm->m_End0 += centre;
DrawSegm->m_Width = (int) round( ibuf[6] * conv_unit );
DrawSegm->SetDrawCoord();
LastModStruct = DrawSegm;
continue;
}
if( params[0].CmpNoCase( wxT( "Pad" ) ) == 0 ) // Pad with no hole (smd pad)
{ // format: Pad [x1 y1 x2 y2 thickness clearance mask "name" "pad_number" flags]
Pad = new D_PAD( this );
Pad->m_PadShape = PAD_RECT;
Pad->m_Masque_Layer = CMP_LAYER | SOLDERMASK_LAYER_CMP | SOLDERPASTE_LAYER_CMP;
// Set shape from flags
iflgidx = params.GetCount() - 2;
if( TestFlags( params[iflgidx], 0x0080, wxT( "onsolder" ) ) )
Pad->m_Masque_Layer = CUIVRE_LAYER | SOLDERMASK_LAYER_CU | SOLDERPASTE_LAYER_CU;
for( unsigned ii = 0; ii < 5; ii++ )
{
if( ii < params.GetCount() - 2 )
{
long dim;
if( params[ii + 2].ToLong( &dim ) )
ibuf[ii] = (int) round( dim * conv_unit );
}
else
ibuf[ii] = 0;
}
// Read name:
// Currently unused
// Read pad number:
if( params.GetCount() > 10 )
{
strncpy( Pad->m_Padname, CONV_TO_UTF8( params[10] ), 4 );
}
Pad->m_Pos.x = (ibuf[0] + ibuf[2]) / 2;
Pad->m_Pos.y = (ibuf[1] + ibuf[3]) / 2;
Pad->m_Size.x = ibuf[4] + abs( ibuf[0] - ibuf[2] );
Pad->m_Size.y = ibuf[4] + abs( ibuf[1] - ibuf[3] );
Pad->m_Pos.x += m_Pos.x;
Pad->m_Pos.y += m_Pos.y;
if( !TestFlags( params[iflgidx], 0x0100, wxT( "square" ) ) )
{
if( Pad->m_Size.x == Pad->m_Size.y )
Pad->m_PadShape = PAD_ROUND;
else
Pad->m_PadShape = PAD_OVAL;
}
if( LastPad == NULL )
{
Pad->Pback = (EDA_BaseStruct*) this;
m_Pads = Pad;
}
else
{
Pad->Pback = (EDA_BaseStruct*) LastPad;
LastPad->Pnext = (EDA_BaseStruct*) Pad;
}
LastPad = Pad;
continue;
}
if( params[0].CmpNoCase( wxT( "Pin" ) ) == 0 ) // Pad with hole (trough pad)
{ // format: Pin[x y Thickness Clearance Mask DrillHole Name Number Flags]
Pad = new D_PAD( this );
Pad->m_PadShape = PAD_ROUND;
Pad->m_Masque_Layer = ALL_CU_LAYERS |
SILKSCREEN_LAYER_CMP |
SOLDERMASK_LAYER_CMP |
SOLDERMASK_LAYER_CU;
iflgidx = params.GetCount() - 2;
if( TestFlags( params[iflgidx], 0x0100, wxT( "square" ) ) )
Pad->m_PadShape = PAD_RECT;
for( unsigned ii = 0; ii < 6; ii++ )
{
if( ii < params.GetCount() - 2 )
{
long dim;
if( params[ii + 2].ToLong( &dim ) )
ibuf[ii] = (int) round( dim * conv_unit );
}
else
ibuf[ii] = 0;
}
// Read name:
// Currently unused
// Read pad number:
if( params.GetCount() > 9 )
{
strncpy( Pad->m_Padname, CONV_TO_UTF8( params[9] ), 4 );
}
Pad->m_Pos.x = ibuf[0];
Pad->m_Pos.y = ibuf[1];
Pad->m_Drill.x = Pad->m_Drill.y = ibuf[5];
Pad->m_Size.x = Pad->m_Size.y = ibuf[3] + Pad->m_Drill.x;
Pad->m_Pos.x += m_Pos.x;
Pad->m_Pos.y += m_Pos.y;
if( (Pad->m_PadShape == PAD_ROUND) && (Pad->m_Size.x != Pad->m_Size.y) )
Pad->m_PadShape = PAD_OVAL;
if( LastPad == NULL )
{
Pad->Pback = (EDA_BaseStruct*) this;
m_Pads = Pad;
}
else
{
Pad->Pback = (EDA_BaseStruct*) LastPad;
LastPad->Pnext = (EDA_BaseStruct*) Pad;
}
LastPad = Pad;
continue;
}
}
fclose( cmpfile );
if( m_Value->m_Text.IsEmpty() )
m_Value->m_Text = wxT( "Val**" );
if( m_Reference->m_Text.IsEmpty() )
{
wxFileName filename( CmpFullFileName );
m_Reference->m_Text = filename.GetName();
}
/* Recalculate the bounding box */
Set_Rectangle_Encadrement();
return success;
}
/***********************************************************************/
static void Extract_Parameters( wxArrayString& param_list, char* text )
/***********************************************************************/
/* Read a text line and extract params and tokens.
* special chars are:
* [ ] ( ) Begin and end of parameter list and units indicator
* " is a string delimiter
* space is the param separator
* The first word is the keyword
* the second item is one of ( ot [
* other are parameters (number or delimited string)
* last parameter is ) or ]
*/
{
int key;
wxString tmp;
while( *text != 0 )
{
key = *text;
text++;
switch( key )
{
case '[':
case ']':
case '(':
case ')':
if( !tmp.IsEmpty() )
{
param_list.Add( tmp );
tmp.Clear();
}
tmp.Append( key );
param_list.Add( tmp );
tmp.Clear();
break;
case '\n':
case '\r':
case '\t':
case ' ':
if( !tmp.IsEmpty() )
{
param_list.Add( tmp );
tmp.Clear();
}
break;
case '"':
while( *text != 0 )
{
key = *text;
text++;
if( key == '"' )
{
param_list.Add( tmp );
tmp.Clear();
break;
}
else
tmp.Append( key );
}
break;
default:
tmp.Append( key );
break;
}
}
}
/***********************************************************************************/
bool TestFlags( const wxString& flg_string, long flg_mask, const wxChar* flg_name )
/***********************************************************************************/
/** Function TestFlags
* Test flag flg_mask or flg_name.
* @param flg_string = flsg list to test: can be a bit field flag or a list name flsg
* a bit field flag is an hexadecimal value: Ox00020000
* a list name flsg is a string list of flags, comma separated like square,option1
* @param flg_mask = flsg list to test
* @param flg_mask = flsg list to test
* @return true if found
*/
{
wxString strnumber;
if( flg_string.StartsWith( wxT( "0x" ),
&strnumber ) || flg_string.StartsWith( wxT( "0X" ), &strnumber ) )
{
long lflags;
if( strnumber.ToLong( &lflags, 16 ) )
if( lflags & flg_mask )
return true;
}
else if( flg_string.Contains( flg_name ) )
return true;
return false;
}