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kicad/pcbnew/drc.cpp

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/****************************/
/* DRC control */
/****************************/
#include "fctsys.h"
#include "gr_basic.h"
#include "common.h"
#include "pcbnew.h"
#include "autorout.h"
#include "trigo.h"
#include "protos.h"
/* variables locales */
class WinEDA_DrcFrame;
WinEDA_DrcFrame* DrcFrame;
/* saving drc options */
static bool s_Pad2PadTestOpt = true;
static bool s_UnconnectedTestOpt = true;
static bool s_ZonesTestOpt = false;
static bool s_CreateRptFileOpt = false;
static FILE* s_RptFile = NULL;
static wxString s_RptFilename;
static int ErrorsDRC_Count;
static MARQUEUR* current_marqueur; /* Pour gestion des marqueurs sur pcb */
static bool AbortDrc, DrcInProgress = FALSE;
static int spot_cX, spot_cY; /* position d'elements a tester */
static int finx, finy; // coord relatives de l'extremite du segm de reference
static int segm_angle; // angle d'inclinaison du segment de reference en 0,1 degre
static int segm_long; // longueur du segment de reference
static int xcliplo, ycliplo, xcliphi, ycliphi; /* coord de la surface de securite du segment a comparer */
/* Routines Locales */
static int Pad_to_Pad_Isol( D_PAD* pad_ref, D_PAD* pad, const int dist_min );
static bool Test_Pad_to_Pads_Drc( WinEDA_BasePcbFrame* frame,
wxDC* DC,
D_PAD* pad_ref,
LISTE_PAD* start_buffer,
LISTE_PAD* end_buffer,
int max_size,
bool show_err );
static int TestClearanceSegmToPad( const D_PAD* pad_to_test, int seg_width, int isol );
static int TestMarginToCircle( int cx, int cy, int rayon, int longueur );
static int Tst_Ligne( int x1, int y1, int x2, int y2 );
static void Affiche_Erreur_DRC( WinEDA_DrawPanel* panel, wxDC* DC, BOARD* Pcb,
TRACK* pt_ref, void* pt_item, int errnumber );
static void Affiche_Erreur_DRC( WinEDA_DrawPanel* panel, wxDC* DC,
BOARD* Pcb, D_PAD* pad1, D_PAD* pad2 );
/*******************************************/
/* Frame d'option et execution DRC general */
/*******************************************/
#include "dialog_drc.cpp"
/***************************************************************/
void WinEDA_DrcFrame::ListUnconnectedPads( wxCommandEvent& event )
/***************************************************************/
{
if( (m_Parent->m_Pcb->m_Status_Pcb & LISTE_CHEVELU_OK) == 0 )
{
m_Parent->Compile_Ratsnest( m_DC, TRUE );
}
if( m_Parent->m_Pcb->m_Ratsnest == NULL )
return;
CHEVELU* Ratsnest = m_Parent->m_Pcb->m_Ratsnest;
int draw_mode = GR_SURBRILL | GR_OR;
WinEDA_DrawPanel* panel = m_Parent->DrawPanel;
int ii;
wxString msg;
float convert = 0.0001;
msg = _( "Look for active routes\n" );
m_logWindow->AppendText( msg );
if( s_RptFile )
fprintf( s_RptFile, "%s", CONV_TO_UTF8( msg ) );
m_UnconnectedCount = 0;
for( ii = m_Parent->m_Pcb->GetNumRatsnests(); ii > 0; Ratsnest++, ii-- )
{
if( (Ratsnest->status & CH_ACTIF) == 0 )
continue;
m_UnconnectedCount++;
if( m_UnconnectedCount == 1 )
m_logWindow->AppendText( _( "Unconnected found:\n" ) );
D_PAD* pad = Ratsnest->pad_start;
pad->Draw( panel, m_DC, wxPoint( 0, 0 ), draw_mode );
wxString pad_name = pad->ReturnStringPadName();
wxString module_name = ( (MODULE*) (pad->m_Parent) )->m_Reference->m_Text;
msg.Printf( _( "%d > Pad %s (%s) @ %.4f,%.4f and " ), m_UnconnectedCount,
pad_name.GetData(), module_name.GetData(
), pad->m_Pos.x * convert, pad->m_Pos.y * convert );
m_logWindow->AppendText( msg );
if( s_RptFile )
fprintf( s_RptFile, "%s", CONV_TO_UTF8( msg ) );
pad = Ratsnest->pad_end;
pad->Draw( panel, m_DC, wxPoint( 0, 0 ), draw_mode );
pad_name = pad->ReturnStringPadName();
module_name = ( (MODULE*) (pad->m_Parent) )->m_Reference->m_Text;
msg.Printf( _( "Pad %s (%s) @ %.4f,%.4f\n" ),
pad_name.GetData(), module_name.GetData(
), pad->m_Pos.x * convert, pad->m_Pos.y * convert );
m_logWindow->AppendText( msg );
if( s_RptFile )
fprintf( s_RptFile, "%s", CONV_TO_UTF8( msg ) );
}
if( m_UnconnectedCount )
msg.Printf( _( "Active routes: %d\n" ), m_UnconnectedCount );
else
msg = _( "OK! (No active routes)\n" );
m_logWindow->AppendText( msg );
if( s_RptFile )
fprintf( s_RptFile, "%s", CONV_TO_UTF8( msg ) );
}
/****************************************************/
void WinEDA_DrcFrame::TestDrc( wxCommandEvent& event )
/****************************************************/
{
int errors;
wxString msg;
if( !DrcInProgress )
{
if( m_CreateRptCtrl->IsChecked() ) // Create a file rpt
{
s_RptFilename = m_RptFilenameCtrl->GetValue();
if( s_RptFilename.IsEmpty() )
OnButtonBrowseRptFileClick( event );
if( !s_RptFilename.IsEmpty() )
s_RptFile = wxFopen( s_RptFilename, wxT( "w" ) );
else
s_RptFile = NULL;
}
if( s_RptFile )
{
fprintf( s_RptFile, "Drc report for %s\n",
CONV_TO_UTF8( m_Parent->m_CurrentScreen->m_FileName ) );
char line[256];
fprintf( s_RptFile, "Created on %s\n", DateAndTime( line ) );
}
s_Pad2PadTestOpt = m_Pad2PadTestCtrl->IsChecked();
s_UnconnectedTestOpt = m_UnconnectedTestCtrl->IsChecked();
s_ZonesTestOpt = m_ZonesTestCtrl->IsChecked();
AbortDrc = FALSE;
m_logWindow->Clear();
g_DesignSettings.m_TrackClearence =
ReturnValueFromTextCtrl( *m_SetClearance, m_Parent->m_InternalUnits );
/* Test DRC errors (clearance errors, bad connections .. */
errors = m_Parent->Test_DRC( m_DC, m_Pad2PadTestCtrl->IsChecked(
), m_ZonesTestCtrl->IsChecked() );
/* Search for active routes (unconnected pads) */
if( m_UnconnectedTestCtrl->IsChecked() )
ListUnconnectedPads( event );
else
m_UnconnectedCount = 0;
if( errors )
msg.Printf( _( "** End Drc: %d errors **\n" ), errors );
else if( m_UnconnectedCount == 0 )
msg = _( "** End Drc: No Error **\n" );
m_logWindow->AppendText( msg );
if( s_RptFile )
fprintf( s_RptFile, "%s", CONV_TO_UTF8( msg ) );
if( s_RptFile )
{
msg.Printf( _( "Report file <%s> created\n" ), s_RptFilename.GetData() );
m_logWindow->AppendText( msg );
fclose( s_RptFile );
s_RptFile = NULL;
}
}
else
wxBell();
}
/*********************************************************/
void WinEDA_DrcFrame::DelDRCMarkers( wxCommandEvent& event )
/*********************************************************/
{
if( !DrcInProgress )
{
m_Parent->Erase_Marqueurs();
m_Parent->DrawPanel->ReDraw( m_DC, TRUE );
}
else
wxBell();
}
/******************************************************/
void WinEDA_PcbFrame::Install_Test_DRC_Frame( wxDC* DC )
/******************************************************/
/* Test des isolements : teste les isolements des pistes et place un
* marqueur sur les divers segments en defaut
* Principe:
* Appelle la routine drc() pour chaque segment de piste existant
*/
{
AbortDrc = FALSE;
DrcFrame = new WinEDA_DrcFrame( this, DC );
DrcFrame->ShowModal(); DrcFrame->Destroy();
DrcFrame = NULL;
}
/************************************************************************/
int WinEDA_PcbFrame::Test_DRC( wxDC* DC, bool TestPad2Pad, bool TestZone )
/************************************************************************/
/* Test des isolements : teste les isolements des pistes et place un
* marqueur sur les divers segments en defaut
* Principe:
* Appelle la routine drc() pour chaque segment de piste existant
*/
{
int ii, jj, old_net;
int flag_err_Drc;
TRACK* pt_segm;
D_PAD* pad;
MARQUEUR* Marqueur;
EDA_BaseStruct* PtStruct;
wxString Line;
#define PRINT_NB_PAD_POS 42
#define PRINT_PAD_ERR_POS 48
#define PRINT_TST_POS 20
#define PRINT_NB_SEGM_POS 26
#define PRINT_TRACK_ERR_POS 32
#define PRINT_NB_ZONESEGM_POS 60
#define PRINT_ZONE_ERR_POS 70
DrcInProgress = TRUE;
ErrorsDRC_Count = 0;
Compile_Ratsnest( DC, TRUE );
MsgPanel->EraseMsgBox();
m_CurrentScreen->SetRefreshReq();
/* Effacement des anciens marqueurs */
Erase_Marqueurs();
if( TestPad2Pad ) /* Test DRC des pads entre eux */
{
Line.Printf( wxT( "%d" ), m_Pcb->m_NbPads );
Affiche_1_Parametre( this, PRINT_NB_PAD_POS, wxT( "NbPad" ), Line, RED );
Affiche_1_Parametre( this, PRINT_PAD_ERR_POS, wxT( "Pad Err" ), wxT( "0" ), LIGHTRED );
if( DrcFrame )
DrcFrame->m_logWindow->AppendText( _( "Tst Pad to Pad\n" ) );
LISTE_PAD* pad_list_start = CreateSortedPadListByXCoord( m_Pcb );
LISTE_PAD* pad_list_limit = &pad_list_start[m_Pcb->m_NbPads];
int max_size = 0;
LISTE_PAD* pad_list;
/* Compute the max size of the pads ( used to stop the test) */
for( pad_list = pad_list_start; pad_list < pad_list_limit; pad_list++ )
{
pad = *pad_list;
if( pad->m_Rayon > max_size )
max_size = pad->m_Rayon;
}
/* Test the pads */
for( pad_list = pad_list_start; pad_list < pad_list_limit; pad_list++ )
{
pad = *pad_list;
if( Test_Pad_to_Pads_Drc( this, DC, pad, pad_list, pad_list_limit, max_size,
TRUE ) == BAD_DRC )
{
Marqueur = current_marqueur;
current_marqueur = NULL;
if( Marqueur == NULL )
{
DisplayError( this, wxT( "Test_Drc(): internal err" ) );
return ErrorsDRC_Count;
}
Line.Printf( wxT( "%d" ), ErrorsDRC_Count );
Affiche_1_Parametre( this, PRINT_PAD_ERR_POS, wxEmptyString, Line, LIGHTRED );
Marqueur->Pnext = m_Pcb->m_Drawings;
Marqueur->Pback = m_Pcb;
PtStruct = m_Pcb->m_Drawings;
if( PtStruct )
PtStruct->Pback = Marqueur;
m_Pcb->m_Drawings = Marqueur;
}
}
free( pad_list_start );
}
/* Test track segments */
Line.Printf( wxT( "%d" ), m_Pcb->m_NbSegmTrack );
Affiche_1_Parametre( this, PRINT_NB_SEGM_POS, _( "SegmNb" ), Line, RED );
Affiche_1_Parametre( this, PRINT_TRACK_ERR_POS, _( "Track Err" ), wxT( "0" ), LIGHTRED );
pt_segm = m_Pcb->m_Track;
if( DrcFrame )
DrcFrame->m_logWindow->AppendText( _( "Tst Tracks\n" ) );
for( ii = 0, old_net = -1, jj = 0;
pt_segm != NULL;
pt_segm = (TRACK*) pt_segm->Pnext, ii++, jj-- )
{
if( pt_segm->Pnext == NULL )
break;
if( jj == 0 )
{
jj = 10;
wxYield();
if( AbortDrc )
{
AbortDrc = FALSE; break;
}
/* Print stats */
Line.Printf( wxT( "%d" ), ii );
Affiche_1_Parametre( this, PRINT_TST_POS, wxT( "Test" ), Line, CYAN );
}
if( old_net != pt_segm->m_NetCode )
{
wxString msg;
jj = 1;
EQUIPOT* equipot = GetEquipot( m_Pcb, pt_segm->m_NetCode );
if( equipot )
msg = equipot->m_Netname + wxT( " " );
else
msg = wxT( "<noname>" );
Affiche_1_Parametre( this, 0, _( "Netname" ), msg, YELLOW );
old_net = pt_segm->m_NetCode;
}
g_HightLigth_NetCode = pt_segm->m_NetCode;
flag_err_Drc = Drc( this, DC, pt_segm, (TRACK*) pt_segm->Pnext, 1 );
if( flag_err_Drc == BAD_DRC )
{
Marqueur = current_marqueur;
current_marqueur = NULL;
if( Marqueur == NULL )
{
DisplayError( this, wxT( "Test_Drc(): internal err" ) );
return ErrorsDRC_Count;
}
Marqueur->Pnext = m_Pcb->m_Drawings;
Marqueur->Pback = m_Pcb;
PtStruct = m_Pcb->m_Drawings;
if( PtStruct )
PtStruct->Pback = Marqueur;
m_Pcb->m_Drawings = Marqueur;
GRSetDrawMode( DC, GR_OR );
pt_segm->Draw( DrawPanel, DC, RED ^ LIGHTRED );
Line.Printf( wxT( "%d" ), ErrorsDRC_Count );
Affiche_1_Parametre( this, PRINT_TRACK_ERR_POS, wxEmptyString, Line, LIGHTRED );
}
}
/* Test zone segments segments */
if( TestZone )
{
m_Pcb->m_NbSegmZone = 0;
for( pt_segm = (TRACK*) m_Pcb->m_Zone; pt_segm != NULL; pt_segm = (TRACK*) pt_segm->Pnext )
m_Pcb->m_NbSegmZone++;
Line.Printf( wxT( "%d" ), m_Pcb->m_NbSegmZone );
Affiche_1_Parametre( this, PRINT_NB_ZONESEGM_POS, _( "SegmNb" ), Line, RED );
Affiche_1_Parametre( this, PRINT_ZONE_ERR_POS, _( "Zone Err" ), wxT( "0" ), LIGHTRED );
if( DrcFrame )
DrcFrame->m_logWindow->AppendText( _( "Tst Zones\n" ) );
pt_segm = (TRACK*) m_Pcb->m_Zone;
for( ii = 0, old_net = -1, jj = 0;
pt_segm != NULL;
pt_segm = (TRACK*) pt_segm->Pnext, ii++, jj-- )
{
if( pt_segm->Pnext == NULL )
break;
if( jj == 0 )
{
jj = 100;
wxYield();
if( AbortDrc )
{
AbortDrc = FALSE; break;
}
/* Print stats */
Line.Printf( wxT( "%d" ), ii );
Affiche_1_Parametre( this, PRINT_TST_POS, wxT( "Test" ), Line, CYAN );
}
if( old_net != pt_segm->m_NetCode )
{
jj = 1;
wxString msg;
EQUIPOT* equipot = GetEquipot( m_Pcb, pt_segm->m_NetCode );
if( equipot )
msg = equipot->m_Netname + wxT( " " );
else
msg = wxT( "<noname>" );
Affiche_1_Parametre( this, 0, _( "Netname" ), msg, YELLOW );
old_net = pt_segm->m_NetCode;
}
g_HightLigth_NetCode = pt_segm->m_NetCode;
/* Test drc with other zone segments, and pads */
flag_err_Drc = Drc( this, DC, pt_segm, (TRACK*) pt_segm->Pnext, 1 );
if( flag_err_Drc == BAD_DRC )
{
Marqueur = current_marqueur;
current_marqueur = NULL;
if( Marqueur == NULL )
{
DisplayError( this, wxT( "Test_Drc(): internal err" ) );
return ErrorsDRC_Count;
}
Marqueur->Pnext = m_Pcb->m_Drawings;
Marqueur->Pback = m_Pcb;
PtStruct = m_Pcb->m_Drawings;
if( PtStruct )
PtStruct->Pback = Marqueur;
m_Pcb->m_Drawings = Marqueur;
GRSetDrawMode( DC, GR_OR );
pt_segm->Draw( DrawPanel, DC, RED ^ LIGHTRED );
Line.Printf( wxT( "%d" ), ErrorsDRC_Count );
Affiche_1_Parametre( this, PRINT_ZONE_ERR_POS, wxEmptyString, Line, LIGHTRED );
}
/* Test drc with track segments */
int tmp = m_Pcb->m_NbPads; m_Pcb->m_NbPads = 0; // Pads already tested: disable pad test
flag_err_Drc = Drc( this, DC, pt_segm, m_Pcb->m_Track, 1 );
m_Pcb->m_NbPads = tmp;
if( flag_err_Drc == BAD_DRC )
{
Marqueur = current_marqueur;
current_marqueur = NULL;
if( Marqueur == NULL )
{
DisplayError( this, wxT( "Test_Drc(): internal err" ) );
return ErrorsDRC_Count;
}
Marqueur->Pnext = m_Pcb->m_Drawings;
Marqueur->Pback = m_Pcb;
PtStruct = m_Pcb->m_Drawings;
if( PtStruct )
PtStruct->Pback = Marqueur;
m_Pcb->m_Drawings = Marqueur;
GRSetDrawMode( DC, GR_OR );
pt_segm->Draw( DrawPanel, DC, RED ^ LIGHTRED );
Line.Printf( wxT( "%d" ), ErrorsDRC_Count );
Affiche_1_Parametre( this, PRINT_ZONE_ERR_POS, wxEmptyString, Line, LIGHTRED );
}
}
}
AbortDrc = FALSE;
DrcInProgress = FALSE;
return ErrorsDRC_Count;
}
/***********************************************************************/
int Drc( WinEDA_BasePcbFrame* frame, wxDC* DC,
TRACK* pt_segment, TRACK* StartBuffer, int show_err )
/***********************************************************************/
/*
* Teste le segment en cours de trace:
* pt_segment = pointeur sur segment a controler
* StartBuffer = adresse de la zone des pistes a controler
* (typiquement m_Pcb->m_Track)
* show_err (flag) si 0 pas d'affichage d'erreur sur ecran
* retourne :
* BAD_DRC (1) si Violation DRC
* OK_DRC (0) si OK
*/
{
int ii;
TRACK* pttrack;
int x0, y0, xf, yf; // coord des extremites du segment teste dans le repere modifie
int dx, dy; // utilise pour calcul des dim x et dim y des segments
int w_dist;
int MaskLayer;
int net_code_ref;
int org_X, org_Y; // Origine sur le PCB des axes du repere centre sur
// l'origine du segment de reference
wxPoint shape_pos;
org_X = pt_segment->m_Start.x; org_Y = pt_segment->m_Start.y;
finx = dx = pt_segment->m_End.x - org_X;
finy = dy = pt_segment->m_End.y - org_Y;
MaskLayer = pt_segment->ReturnMaskLayer();
net_code_ref = pt_segment->m_NetCode;
segm_angle = 0;
if( dx || dy )
{
/* calcul de l'angle d'inclinaison en 0,1 degre */
segm_angle = ArcTangente( dy, dx );
/* Calcul de la longueur du segment en segm_long : dx = longueur */
RotatePoint( &dx, &dy, segm_angle ); /* segm_long = longueur, yf = 0 */
}
/* Ici le segment a ete tourne de segm_angle, et est horizontal, dx > 0 */
segm_long = dx;
/******************************************/
/* Phase 1 : test DRC track to pads :*/
/******************************************/
/* calcul de la distance min aux pads : */
w_dist = (unsigned) (pt_segment->m_Width >> 1 );
for( ii = 0; ii < frame->m_Pcb->m_NbPads; ii++ )
{
D_PAD* pt_pad = frame->m_Pcb->m_Pads[ii];
/* Pas de probleme si les pads sont en surface autre que la couche,
* sauf si le trou de percage gene (cas des pastilles perc<72>s simple
* face sur CI double face */
if( (pt_pad->m_Masque_Layer & MaskLayer ) == 0 )
{
/* We must test the pad hole. In order to use the function "TestClearanceSegmToPad",
* a pseudo pad is used, with a shape and a size like the hole */
if( pt_pad->m_Drill.x == 0 )
continue;
D_PAD pseudo_pad( (MODULE*) NULL );
pseudo_pad.m_Size = pt_pad->m_Drill;
pseudo_pad.m_Pos = pt_pad->m_Pos;
pseudo_pad.m_PadShape = pt_pad->m_DrillShape;
pseudo_pad.m_Orient = pt_pad->m_Orient;
pseudo_pad.ComputeRayon();
spot_cX = pseudo_pad.m_Pos.x - org_X;
spot_cY = pseudo_pad.m_Pos.y - org_Y;
if( TestClearanceSegmToPad( &pseudo_pad, w_dist,
g_DesignSettings.m_TrackClearence ) != OK_DRC )
{
ErrorsDRC_Count++;
if( show_err )
Affiche_Erreur_DRC( frame->DrawPanel, DC,
frame->m_Pcb, pt_segment, pt_pad, 0 );
return BAD_DRC;
}
continue;
}
/* Le pad doit faire partie d'un net mais pas de probleme
* si le pad est du meme net */
if( pt_pad->m_NetCode && (net_code_ref == pt_pad->m_NetCode) )
continue;
/* Test DRC pour les pads */
shape_pos = pt_pad->ReturnShapePos();
spot_cX = shape_pos.x - org_X;
spot_cY = shape_pos.y - org_Y;
if( TestClearanceSegmToPad( pt_pad, w_dist, g_DesignSettings.m_TrackClearence ) == OK_DRC )
continue;
/* extremite sur pad ou defaut d'isolation trouve */
else
{
ErrorsDRC_Count++;
if( show_err )
Affiche_Erreur_DRC( frame->DrawPanel, DC,
frame->m_Pcb, pt_segment, pt_pad, 1 );
return BAD_DRC;
}
}
/**********************************************/
/* Phase 2 : test DRC avec les autres pistes :*/
/**********************************************/
/* Ici le segment de reference est sur l'axe X */
/* Comparaison du segment de reference aux autres segments de piste */
pttrack = StartBuffer;
for( ; pttrack != NULL; pttrack = (TRACK*) pttrack->Pnext )
{
//pas de probleme si le segment a tester est du meme net:
if( net_code_ref == pttrack->m_NetCode )
continue;
//pas de probleme si le segment a tester est sur une autre couche :
if( ( MaskLayer & pttrack->ReturnMaskLayer() ) == 0 )
continue;
/* calcul de la Distance mini = Isol+ rayon ou demi largeur seg ref
+ rayon ou demi largeur seg a comparer */
w_dist = pt_segment->m_Width >> 1;
w_dist += pttrack->m_Width >> 1;
w_dist += g_DesignSettings.m_TrackClearence;
/* si le segment de reference est une via, le traitement est ici */
if( pt_segment->m_StructType == TYPEVIA )
{
int orgx, orgy; // origine du repere d'axe X = segment a comparer
int angle = 0; // angle du segment a tester;
orgx = pttrack->m_Start.x; orgy = pttrack->m_Start.y;
dx = pttrack->m_End.x - orgx; dy = pttrack->m_End.y - orgy;
x0 = pt_segment->m_Start.x - orgx; y0 = pt_segment->m_Start.y - orgy;
if( pttrack->m_StructType == TYPEVIA ) /* Tst distance entre 2 vias */
{
if( (int) hypot( (float) x0, (float) y0 ) < w_dist )
{
ErrorsDRC_Count++;
if( show_err )
Affiche_Erreur_DRC( frame->DrawPanel,
DC,
frame->m_Pcb,
pt_segment,
pttrack,
21 );
return BAD_DRC;
}
}
else /* Tst distance de via a segment */
{
/* calcul de l'angle */
angle = ArcTangente( dy, dx );
/* Calcul des coord dans le nouveau repere */
RotatePoint( &dx, &dy, angle );
RotatePoint( &x0, &y0, angle );
if( TestMarginToCircle( x0, y0, w_dist, dx ) == BAD_DRC )
{
ErrorsDRC_Count++;
if( show_err )
Affiche_Erreur_DRC( frame->DrawPanel,
DC,
frame->m_Pcb,
pt_segment,
pttrack,
20 );
return BAD_DRC;
}
}
continue;
}
/* calcule x0,y0, xf,yf = coord de debut et fin du segment de piste
* a tester, dans le repere axe X = segment de reference */
x0 = pttrack->m_Start.x - org_X; y0 = pttrack->m_Start.y - org_Y;
xf = pttrack->m_End.x - org_X; yf = pttrack->m_End.y - org_Y;
RotatePoint( &x0, &y0, segm_angle ); RotatePoint( &xf, &yf, segm_angle );
if( pttrack->m_StructType == TYPEVIA )
{
if( TestMarginToCircle( x0, y0, w_dist, segm_long ) == OK_DRC )
continue;
ErrorsDRC_Count++;
if( show_err )
Affiche_Erreur_DRC( frame->DrawPanel, DC, frame->m_Pcb, pt_segment, pttrack, 21 );
return BAD_DRC;
}
/*
* le segment de reference est Horizontal, par suite des modifs d'axe.
* 3 cas : segment a comparer parallele, perp ou incline
*/
if( y0 == yf ) // segments paralleles
{
if( abs( y0 ) >= w_dist )
continue;
if( x0 > xf )
EXCHG( x0, xf ); /* pour que x0 <= xf */
if( x0 > (-w_dist) && x0 < (segm_long + w_dist) ) /* Risque de defaut */
{
/* test fin tenant compte des formes arrondies des extremites */
if( x0 >= 0 && x0 <= segm_long )
{
ErrorsDRC_Count++;
if( show_err )
Affiche_Erreur_DRC( frame->DrawPanel,
DC,
frame->m_Pcb,
pt_segment,
pttrack,
2 );
return BAD_DRC;
}
if( TestMarginToCircle( x0, y0, w_dist, segm_long ) == BAD_DRC )
{
ErrorsDRC_Count++;
if( show_err )
Affiche_Erreur_DRC( frame->DrawPanel,
DC,
frame->m_Pcb,
pt_segment,
pttrack,
2 );
return BAD_DRC;
}
}
if( xf > (-w_dist) && xf < (segm_long + w_dist) )
{
/* test fin tenant compte des formes arrondies des extremites */
if( xf >= 0 && xf <= segm_long )
{
ErrorsDRC_Count++;
if( show_err )
Affiche_Erreur_DRC( frame->DrawPanel,
DC,
frame->m_Pcb,
pt_segment,
pttrack,
3 );
return BAD_DRC;
}
if( TestMarginToCircle( xf, yf, w_dist, segm_long ) == BAD_DRC )
{
ErrorsDRC_Count++;
if( show_err )
Affiche_Erreur_DRC( frame->DrawPanel,
DC,
frame->m_Pcb,
pt_segment,
pttrack,
3 );
return BAD_DRC;
}
}
if( x0 <=0 && xf >= 0 )
{
ErrorsDRC_Count++;
if( show_err )
Affiche_Erreur_DRC( frame->DrawPanel, DC, frame->m_Pcb, pt_segment, pttrack, 4 );
return BAD_DRC;
}
}
else if( x0 == xf ) // segments perpendiculaires
{
if( ( x0 <= (-w_dist) ) || ( x0 >= (segm_long + w_dist) ) )
continue;
/* test si les segments se croisent */
if( y0 > yf )
EXCHG( y0, yf );
if( (y0 < 0) && (yf > 0) )
{
ErrorsDRC_Count++;
if( show_err )
Affiche_Erreur_DRC( frame->DrawPanel, DC, frame->m_Pcb, pt_segment, pttrack, 6 );
return BAD_DRC;
}
/* ici l'erreur est due a une extremite pres d'une extremite du segm
* de reference */
if( TestMarginToCircle( x0, y0, w_dist, segm_long ) == BAD_DRC )
{
ErrorsDRC_Count++;
if( show_err )
Affiche_Erreur_DRC( frame->DrawPanel, DC, frame->m_Pcb, pt_segment, pttrack, 7 );
return BAD_DRC;
}
if( TestMarginToCircle( xf, yf, w_dist, segm_long ) == BAD_DRC )
{
ErrorsDRC_Count++;
if( show_err )
Affiche_Erreur_DRC( frame->DrawPanel, DC, frame->m_Pcb, pt_segment, pttrack, 8 );
return BAD_DRC;
}
}
else // segments quelconques entre eux */
{
int bflag = OK_DRC;
/* calcul de la "surface de securite du segment de reference */
/* premiere passe : la piste est assimilee a un rectangle */
xcliplo = ycliplo = -w_dist;
xcliphi = segm_long + w_dist; ycliphi = w_dist;
bflag = Tst_Ligne( x0, y0, xf, yf );
if( bflag == BAD_DRC )
{
/* 2eme passe : la piste a des extremites arrondies.
* Si le defaut de drc est du a une extremite : le calcul
* est affine pour tenir compte de cet arrondi */
xcliplo = 0; xcliphi = segm_long;
bflag = Tst_Ligne( x0, y0, xf, yf );
if( bflag == BAD_DRC )
{
ErrorsDRC_Count++;
if( show_err )
Affiche_Erreur_DRC( frame->DrawPanel,
DC,
frame->m_Pcb,
pt_segment,
pttrack,
9 );
return BAD_DRC;
}
else // L'erreur est due a une extremite du segment de reference:
{
// il faut tester les extremites de ce segment
int angle, rx0, ry0, rxf, ryf;
x0 = pttrack->m_Start.x; y0 = pttrack->m_Start.y;
xf = pttrack->m_End.x; yf = pttrack->m_End.y;
dx = xf - x0; dy = yf - y0;
/* calcul de l'angle d'inclinaison en 0,1 degre */
angle = ArcTangente( dy, dx );
/* Calcul de la longueur du segment: dx = longueur */
RotatePoint( &dx, &dy, angle );
/* calcul des coord du segment de reference ds le repere
* d'axe X = segment courant en tst */
rx0 = pt_segment->m_Start.x - x0;
ry0 = pt_segment->m_Start.y - y0;
rxf = pt_segment->m_End.x - x0;
ryf = pt_segment->m_End.y - y0;
RotatePoint( &rx0, &ry0, angle );
RotatePoint( &rxf, &ryf, angle );
if( TestMarginToCircle( rx0, ry0, w_dist, dx ) == BAD_DRC )
{
ErrorsDRC_Count++;
if( show_err )
Affiche_Erreur_DRC( frame->DrawPanel,
DC,
frame->m_Pcb,
pt_segment,
pttrack,
10 );
return BAD_DRC;
}
if( TestMarginToCircle( rxf, ryf, w_dist, dx ) == BAD_DRC )
{
ErrorsDRC_Count++;
if( show_err )
Affiche_Erreur_DRC( frame->DrawPanel,
DC,
frame->m_Pcb,
pt_segment,
pttrack,
11 );
return BAD_DRC;
}
}
}
}
}
return OK_DRC;
}
/*****************************************************************************/
static bool Test_Pad_to_Pads_Drc( WinEDA_BasePcbFrame* frame,
wxDC* DC,
D_PAD* pad_ref,
LISTE_PAD* start_buffer,
LISTE_PAD* end_buffer,
int max_size,
bool show_err )
/*****************************************************************************/
/* Teste l'isolation de pad_ref avec les autres pads.
* end_buffer = upper limit of the pad list.
* max_size = size of the biggest pad (used to stop the test when the X distance is > max_size)
*/
{
int MaskLayer;
D_PAD* pad;
LISTE_PAD* pad_list = start_buffer;
MaskLayer = pad_ref->m_Masque_Layer & ALL_CU_LAYERS;
int x_limite = max_size + g_DesignSettings.m_TrackClearence +
pad_ref->m_Rayon + pad_ref->m_Pos.x;
for( ; pad_list < end_buffer; pad_list++ )
{
pad = *pad_list;
if( pad == pad_ref )
continue;
/* We can stop the test when pad->m_Pos.x > x_limite
* because the list is sorted by X values */
if( pad->m_Pos.x > x_limite )
break;
/* Pas de probleme si les pads ne sont pas sur les memes couches cuivre*/
if( (pad->m_Masque_Layer & MaskLayer ) == 0 )
continue;
/* Le pad doit faire partie d'un net,
* mais pas de probleme si les pads sont du meme net */
if( pad->m_NetCode && (pad_ref->m_NetCode == pad->m_NetCode) )
continue;
/* pas de pb si les pads sont du meme module et
* de la meme reference ( pads multiples ) */
if( (pad->m_Parent == pad_ref->m_Parent) && (pad->m_NumPadName == pad_ref->m_NumPadName) )
continue;
if( Pad_to_Pad_Isol( pad_ref, pad, g_DesignSettings.m_TrackClearence ) == OK_DRC )
continue;
else /* defaut d'isolation trouve */
{
ErrorsDRC_Count++;
if( show_err )
Affiche_Erreur_DRC( frame->DrawPanel, DC, frame->m_Pcb, pad_ref, pad );
return BAD_DRC;
}
}
return OK_DRC;
}
/**************************************************************************************/
static int Pad_to_Pad_Isol( D_PAD* pad_ref, D_PAD* pad, const int dist_min )
/***************************************************************************************/
/* Return OK_DRC si clearance between pad_ref and pad is >= dist_min
* or BAD_DRC if not */
{
wxPoint rel_pos;
int dist, diag;
wxPoint shape_pos;
int pad_angle;
rel_pos = pad->ReturnShapePos();
shape_pos = pad_ref->ReturnShapePos();
// rel_pos is pad position relative to the pad_ref position
rel_pos.x -= shape_pos.x;
rel_pos.y -= shape_pos.y;
dist = (int) hypot( (double) rel_pos.x, (double) rel_pos.y );
diag = OK_DRC;
/* tst rapide: si les cercles exinscrits sont distants de dist_min au moins,
* il n'y a pas de risque: */
if( (dist - pad_ref->m_Rayon - pad->m_Rayon) >= dist_min )
return OK_DRC;
/* Ici les pads sont proches et les cercles exinxcrits sont trop proches
* Selon les formes relatives il peut y avoir ou non erreur */
bool swap_pads = false;
if( (pad_ref->m_PadShape != CIRCLE) && (pad->m_PadShape == CIRCLE) )
swap_pads = true;
else if( (pad_ref->m_PadShape != OVALE) && (pad->m_PadShape == OVALE) )
swap_pads = true;
if( swap_pads )
{
EXCHG( pad_ref, pad );
rel_pos.x = -rel_pos.x;
rel_pos.y = -rel_pos.y;
}
switch( pad_ref->m_PadShape )
{
case CIRCLE: // pad_ref is like a track segment with a null lenght
segm_long = 0;
segm_angle = 0;
finx = finy = 0;
spot_cX = rel_pos.x;
spot_cY = rel_pos.y;
diag = TestClearanceSegmToPad( pad, pad_ref->m_Rayon, dist_min );
break;
case RECT:
RotatePoint( &rel_pos.x, &rel_pos.y, pad_ref->m_Orient );
pad_angle = pad_ref->m_Orient + pad->m_Orient; // pad_angle = pad orient relative to the pad_ref orient
NORMALIZE_ANGLE_POS( pad_angle );
if( pad->m_PadShape == RECT )
{
wxSize size = pad->m_Size;
if( (pad_angle == 0) || (pad_angle == 900) || (pad_angle == 1800) ||
(pad_angle == 2700) )
{
if( (pad_angle == 900) || (pad_angle == 2700) )
{
EXCHG( size.x, size.y );
}
// Test DRC:
diag = BAD_DRC;
rel_pos.x = ABS( rel_pos.x ); rel_pos.y = ABS( rel_pos.y );
if( ( rel_pos.x - ( (size.x + pad_ref->m_Size.x) / 2 ) ) >= dist_min )
diag = OK_DRC;
if( ( rel_pos.y - ( (size.y + pad_ref->m_Size.y) / 2 ) ) >= dist_min )
diag = OK_DRC;
}
else // Any other orient
{
/* TODO : any orient ... */
}
}
break;
case OVALE: /* an oval pad is like a track segment */
{
/* Create and test a track segment with same dimensions */
int segm_width;
segm_angle = pad_ref->m_Orient; // Segment orient.
if( pad_ref->m_Size.y < pad_ref->m_Size.x ) /* We suppose the pad is an horizontal oval */
{
segm_width = pad_ref->m_Size.y;
segm_long = pad_ref->m_Size.x - pad_ref->m_Size.y;
}
else // it was a vertical oval, change to a rotated horizontal one
{
segm_width = pad_ref->m_Size.x;
segm_long = pad_ref->m_Size.y - pad_ref->m_Size.x;
segm_angle += 900;
}
/* the start point must be 0,0 and currently rel_pos is relative the center of pad coordinate */
int sx = -segm_long / 2, sy = 0; // Start point coordinate of the horizontal equivalent segment
RotatePoint( &sx, &sy, segm_angle ); // True start point coordinate of the equivalent segment
spot_cX = rel_pos.x + sx;
spot_cY = rel_pos.y + sy; // pad position / segment origin
finx = -sx;
finy = -sy; // end of segment coordinate
diag = TestClearanceSegmToPad( pad, segm_width / 2, dist_min );
break;
}
default:
/* TODO...*/
break;
}
return diag;
}
/***************************************************************************/
static int TestClearanceSegmToPad( const D_PAD* pad_to_test, int w_segm, int dist_min )
/****************************************************************************/
/*
* Routine adaptee de la "distance()" (LOCATE.CPP)
* teste la distance du pad au segment de droite en cours
*
* retourne:
* 0 si distance >= dist_min
* 1 si distance < dist_min
* Parametres d'appel:
* pad_to_test = pointeur sur le pad a tester
* w_segm = demi largeur du segment a tester
* dist_min = marge a respecter
*
* en variables globales
* segm_long = longueur du segment en test
* segm_angle = angle d'inclinaison du segment;
* finx, finy = coord fin du segment / origine
* spot_cX, spot_cY = position du pad / origine du segment
*/
{
int p_dimx, p_dimy; /* demi - dimensions X et Y du pad a controler */
int bflag;
int orient;
int x0, y0, xf, yf;
int seuil;
int deltay;
seuil = w_segm + dist_min;
p_dimx = pad_to_test->m_Size.x >> 1;
p_dimy = pad_to_test->m_Size.y >> 1;
if( pad_to_test->m_PadShape == CIRCLE )
{
/* calcul des coord centre du pad dans le repere axe X confondu
* avec le segment en tst */
RotatePoint( &spot_cX, &spot_cY, segm_angle );
return TestMarginToCircle( spot_cX, spot_cY, seuil + p_dimx, segm_long );
}
else
{
/* calcul de la "surface de securite" du pad de reference */
xcliplo = spot_cX - seuil - p_dimx;
ycliplo = spot_cY - seuil - p_dimy;
xcliphi = spot_cX + seuil + p_dimx;
ycliphi = spot_cY + seuil + p_dimy;
x0 = y0 = 0;
xf = finx;
yf = finy;
orient = pad_to_test->m_Orient;
RotatePoint( &x0, &y0, spot_cX, spot_cY, -orient );
RotatePoint( &xf, &yf, spot_cX, spot_cY, -orient );
bflag = Tst_Ligne( x0, y0, xf, yf );
if( bflag == OK_DRC )
return OK_DRC;
/* Erreur DRC : analyse fine de la forme de la pastille */
switch( pad_to_test->m_PadShape )
{
default:
return BAD_DRC;
case OVALE:
/* test de la pastille ovale ramenee au type ovale vertical */
if( p_dimx > p_dimy )
{
EXCHG( p_dimx, p_dimy ); orient += 900;
if( orient >= 3600 )
orient -= 3600;
}
deltay = p_dimy - p_dimx;
/* ici: p_dimx = rayon,
* delta = dist centre cercles a centre pad */
/* Test du rectangle separant les 2 demi cercles */
xcliplo = spot_cX - seuil - p_dimx;
ycliplo = spot_cY - w_segm - deltay;
xcliphi = spot_cX + seuil + p_dimx;
ycliphi = spot_cY + w_segm + deltay;
bflag = Tst_Ligne( x0, y0, xf, yf );
if( bflag == BAD_DRC )
return BAD_DRC;
/* test des 2 cercles */
x0 = spot_cX; /* x0,y0 = centre du cercle superieur du pad ovale */
y0 = spot_cY + deltay;
RotatePoint( &x0, &y0, spot_cX, spot_cY, orient );
RotatePoint( &x0, &y0, segm_angle );
bflag = TestMarginToCircle( x0, y0, p_dimx + seuil, segm_long );
if( bflag == BAD_DRC )
return BAD_DRC;
x0 = spot_cX; /* x0,y0 = centre du cercle inferieur du pad ovale */
y0 = spot_cY - deltay;
RotatePoint( &x0, &y0, spot_cX, spot_cY, orient );
RotatePoint( &x0, &y0, segm_angle );
bflag = TestMarginToCircle( x0, y0, p_dimx + seuil, segm_long );
if( bflag == BAD_DRC )
return BAD_DRC;
break;
case RECT: /* 2 rectangle + 4 1/4 cercles a tester */
/* Test du rectangle dimx + seuil, dimy */
xcliplo = spot_cX - p_dimx - seuil;
ycliplo = spot_cY - p_dimy;
xcliphi = spot_cX + p_dimx + seuil;
ycliphi = spot_cY + p_dimy;
bflag = Tst_Ligne( x0, y0, xf, yf );
if( bflag == BAD_DRC )
{
return BAD_DRC;
}
/* Test du rectangle dimx , dimy + seuil */
xcliplo = spot_cX - p_dimx;
ycliplo = spot_cY - p_dimy - seuil;
xcliphi = spot_cX + p_dimx;
ycliphi = spot_cY + p_dimy + seuil;
bflag = Tst_Ligne( x0, y0, xf, yf );
if( bflag == BAD_DRC )
{
return BAD_DRC;
}
/* test des 4 cercles ( surface d'solation autour des sommets */
/* test du coin sup. gauche du pad */
x0 = spot_cX - p_dimx;
y0 = spot_cY - p_dimy;
RotatePoint( &x0, &y0, spot_cX, spot_cY, orient );
RotatePoint( &x0, &y0, segm_angle );
bflag = TestMarginToCircle( x0, y0, seuil, segm_long );
if( bflag == BAD_DRC )
{
return BAD_DRC;
}
/* test du coin sup. droit du pad */
x0 = spot_cX + p_dimx;
y0 = spot_cY - p_dimy;
RotatePoint( &x0, &y0, spot_cX, spot_cY, orient );
RotatePoint( &x0, &y0, segm_angle );
bflag = TestMarginToCircle( x0, y0, seuil, segm_long );
if( bflag == BAD_DRC )
{
return BAD_DRC;
}
/* test du coin inf. gauche du pad */
x0 = spot_cX - p_dimx;
y0 = spot_cY + p_dimy;
RotatePoint( &x0, &y0, spot_cX, spot_cY, orient );
RotatePoint( &x0, &y0, segm_angle );
bflag = TestMarginToCircle( x0, y0, seuil, segm_long );
if( bflag == BAD_DRC )
{
return BAD_DRC;
}
/* test du coin inf. droit du pad */
x0 = spot_cX + p_dimx;
y0 = spot_cY + p_dimy;
RotatePoint( &x0, &y0, spot_cX, spot_cY, orient );
RotatePoint( &x0, &y0, segm_angle );
bflag = TestMarginToCircle( x0, y0, seuil, segm_long );
if( bflag == BAD_DRC )
{
return BAD_DRC;
}
break;
}
}
return OK_DRC;
}
/*******************************************************************/
static int TestMarginToCircle( int cx, int cy, int rayon, int longueur )
/*******************************************************************/
/*
* Routine analogue a TestClearanceSegmToPad.
* Calcul de la distance d'un cercle (via ronde, extremite de piste)
* au segment de droite en cours de controle (segment de reference dans
* son repere )
* parametres:
* cx, cy: centre du cercle (surface ronde) a tester, dans le repere
* segment de reference
* rayon = rayon du cercle
* longueur = longueur du segment dans son repere (i.e. coord de fin)
* retourne:
* OK_DRC si distance >= rayon
* BAD_DRC si distance < rayon
*/
{
if( abs( cy ) > rayon )
return OK_DRC;
if( (cx >= -rayon ) && ( cx <= (longueur + rayon) ) )
{
if( (cx >= 0) && (cx <= longueur) )
return BAD_DRC;
if( cx > longueur )
cx -= longueur;
if( hypot( (double) cx, (double) cy ) < rayon )
return BAD_DRC;
}
return OK_DRC;
}
/******************************************************************************/
static void Affiche_Erreur_DRC( WinEDA_DrawPanel* panel, wxDC* DC, BOARD* Pcb,
TRACK* pt_ref, void* pt_item, int errnumber )
/******************************************************************************/
/* affiche les erreurs de DRC :
* Message d'erreur
+
* Marqueur
* number = numero d'identification
*/
{
wxPoint erc_pos;
TRACK* pt_segm;
wxString msg;
wxString tracktype, netname1, netname2;
EQUIPOT* equipot = GetEquipot( Pcb, pt_ref->m_NetCode );
if( equipot )
netname1 = equipot->m_Netname;
else
netname1 = wxT( "<noname>" );
netname2 = wxT( "<noname>" );
tracktype = wxT( "Track" );
if( pt_ref->m_StructType == TYPEVIA )
tracktype = wxT( "Via" );
if( pt_ref->m_StructType == TYPEZONE )
tracktype = wxT( "Zone" );
if( ( (EDA_BaseStruct*) pt_item )->m_StructType == TYPEPAD )
{
D_PAD* pad = (D_PAD*) pt_item;
equipot = GetEquipot( Pcb, pad->m_NetCode );
if( equipot )
netname2 = equipot->m_Netname;
erc_pos = pad->m_Pos;
wxString pad_name = pad->ReturnStringPadName();
wxString module_name = ( (MODULE*) (pad->m_Parent) )->m_Reference->m_Text;
msg.Printf( _( "%d Drc Err %d %s (net %s)and PAD %s (%s) net %s @ %d,%d\n" ),
ErrorsDRC_Count, errnumber, tracktype.GetData(),
netname1.GetData(),
pad_name.GetData(), module_name.GetData(),
netname2.GetData(),
erc_pos.x, erc_pos.y );
}
else /* erreur sur segment de piste */
{
pt_segm = (TRACK*) pt_item;
equipot = GetEquipot( Pcb, pt_segm->m_NetCode );
if( equipot )
netname2 = equipot->m_Netname;
erc_pos = pt_segm->m_Start;
if( pt_segm->m_StructType == TYPEVIA )
{
msg.Printf( _( "%d Err type %d: %s (net %s) and VIA (net %s) @ %d,%d\n" ),
ErrorsDRC_Count, errnumber, tracktype.GetData(),
netname1.GetData(), netname2.GetData(),
erc_pos.x, erc_pos.y );
}
else
{
wxPoint erc_pos_f = pt_segm->m_End;
if( hypot( (double) (erc_pos_f.x - pt_ref->m_End.x),
(double) (erc_pos_f.y - pt_ref->m_End.y) )
< hypot( (double) (erc_pos.x - pt_ref->m_End.x),
(double) (erc_pos.y - pt_ref->m_End.y) ) )
{
EXCHG( erc_pos_f.x, erc_pos.x ); EXCHG( erc_pos_f.y, erc_pos.y );
}
msg.Printf( _( "%d Err type %d: %s (net %s) and track (net %s) @ %d,%d\n" ),
ErrorsDRC_Count, errnumber, tracktype.GetData(),
netname1.GetData(), netname2.GetData(),
erc_pos.x, erc_pos.y );
}
}
if( DrcFrame )
DrcFrame->m_logWindow->AppendText( msg );
else
panel->m_Parent->Affiche_Message( msg );
if( s_RptFile )
fprintf( s_RptFile, "%s", CONV_TO_UTF8( msg ) );
if( current_marqueur == NULL )
current_marqueur = new MARQUEUR( Pcb );
current_marqueur->m_Pos = wxPoint( erc_pos.x, erc_pos.y );
current_marqueur->m_Color = WHITE;
current_marqueur->m_Diag = msg;
current_marqueur->Draw( panel, DC, GR_OR );
}
/******************************************************************************/
static void Affiche_Erreur_DRC( WinEDA_DrawPanel* panel, wxDC* DC, BOARD* Pcb,
D_PAD* pad1, D_PAD* pad2 )
/******************************************************************************/
/* affiche les erreurs de DRC :
* Message d'erreur
+
* Marqueur
* number = numero d'identification
*/
{
wxString msg;
wxString pad_name1 = pad1->ReturnStringPadName();
wxString module_name1 = ( (MODULE*) (pad1->m_Parent) )->m_Reference->m_Text;
wxString pad_name2 = pad2->ReturnStringPadName();
wxString module_name2 = ( (MODULE*) (pad2->m_Parent) )->m_Reference->m_Text;
wxString netname1, netname2;
EQUIPOT* equipot = GetEquipot( Pcb, pad1->m_NetCode );
if( equipot )
netname1 = equipot->m_Netname;
else
netname1 = wxT( "<noname>" );
equipot = GetEquipot( Pcb, pad2->m_NetCode );
if( equipot )
netname2 = equipot->m_Netname;
else
netname2 = wxT( "<noname>" );
msg.Printf( _( "%d Drc Err: PAD %s (%s) net %s @ %d,%d and PAD %s (%s) net %s @ %d,%d\n" ),
ErrorsDRC_Count, pad_name1.GetData(), module_name1.GetData(),
netname1.GetData(), pad1->m_Pos.x, pad1->m_Pos.y,
pad_name2.GetData(), module_name2.GetData(),
netname2.GetData(), pad2->m_Pos.x, pad2->m_Pos.y );
if( DrcFrame )
DrcFrame->m_logWindow->AppendText( msg );
else
panel->m_Parent->Affiche_Message( msg );
if( s_RptFile )
fprintf( s_RptFile, "%s", CONV_TO_UTF8( msg ) );
if( current_marqueur == NULL )
current_marqueur = new MARQUEUR( Pcb );
current_marqueur->m_Pos = pad1->m_Pos;
current_marqueur->m_Color = WHITE;
current_marqueur->m_Diag = msg;
current_marqueur->Draw( panel, DC, GR_OR );
}
/**********************************************/
/* int Tst_Ligne(int x1,int y1,int x2,int y2) */
/**********************************************/
/* Routine utilisee pour tester si une piste est en contact avec une autre piste.
*
* Cette routine controle si la ligne (x1,y1 x2,y2) a une partie s'inscrivant
* dans le cadre (xcliplo,ycliplo xcliphi,ycliphi) (variables globales,
* locales a ce fichier)
*
* Retourne OK_DRC si aucune partie commune
* Retourne BAD_DRC si partie commune
*/
#define us unsigned int
static inline int USCALE( us arg, us num, us den )
{
int ii;
ii = (int) ( ( (float) arg * num ) / den );
return ii;
}
#define WHEN_OUTSIDE return (OK_DRC)
#define WHEN_INSIDE
static int Tst_Ligne( int x1, int y1, int x2, int y2 )
{
int temp;
do {
if( x1 > x2 )
{
EXCHG( x1, x2 ); EXCHG( y1, y2 );
}
if( (x2 < xcliplo) || (x1 > xcliphi) )
{
WHEN_OUTSIDE;
}
if( y1 < y2 )
{
if( (y2 < ycliplo) || (y1 > ycliphi) )
{
WHEN_OUTSIDE;
}
if( y1 < ycliplo )
{
temp = USCALE( (x2 - x1), (ycliplo - y1), (y2 - y1) );
if( (x1 += temp) > xcliphi )
{
WHEN_OUTSIDE;
}
y1 = ycliplo;
WHEN_INSIDE;
}
if( y2 > ycliphi )
{
temp = USCALE( (x2 - x1), (y2 - ycliphi), (y2 - y1) );
if( (x2 -= temp) < xcliplo )
{
WHEN_OUTSIDE;
}
y2 = ycliphi;
WHEN_INSIDE;
}
if( x1 < xcliplo )
{
temp = USCALE( (y2 - y1), (xcliplo - x1), (x2 - x1) );
y1 += temp; x1 = xcliplo;
WHEN_INSIDE;
}
if( x2 > xcliphi )
{
temp = USCALE( (y2 - y1), (x2 - xcliphi), (x2 - x1) );
y2 -= temp; x2 = xcliphi;
WHEN_INSIDE;
}
}
else
{
if( (y1 < ycliplo) || (y2 > ycliphi) )
{
WHEN_OUTSIDE;
}
if( y1 > ycliphi )
{
temp = USCALE( (x2 - x1), (y1 - ycliphi), (y1 - y2) );
if( (x1 += temp) > xcliphi )
{
WHEN_OUTSIDE;
}
y1 = ycliphi;
WHEN_INSIDE;
}
if( y2 < ycliplo )
{
temp = USCALE( (x2 - x1), (ycliplo - y2), (y1 - y2) );
if( (x2 -= temp) < xcliplo )
{
WHEN_OUTSIDE;
}
y2 = ycliplo;
WHEN_INSIDE;
}
if( x1 < xcliplo )
{
temp = USCALE( (y1 - y2), (xcliplo - x1), (x2 - x1) );
y1 -= temp; x1 = xcliplo;
WHEN_INSIDE;
}
if( x2 > xcliphi )
{
temp = USCALE( (y1 - y2), (x2 - xcliphi), (x2 - x1) );
y2 += temp; x2 = xcliphi;
WHEN_INSIDE;
}
}
} while( 0 );
if( ( (x2 + x1) / 2 <= xcliphi ) && ( (x2 + x1) / 2 >= xcliplo ) \
&& ( (y2 + y1) / 2 <= ycliphi ) && ( (y2 + y1) / 2 >= ycliplo ) )
{
return BAD_DRC;
}
else
return OK_DRC;
}
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