static void calcule_connexite_1_net(TRACK* pt_start_conn,TRACK* pt_end_conn)
/***************************************************************************/
/* calcule la connexite d'un net constitue de segments de piste consecutifs.
Entree:
pt_start_conn = adresse du 1er segment ( debut du net )
pt_end_conn = adr de fin (dernier segment)
Les connexions relatives aux pads doivent etre deja calculees, car elles
ne sont pas ici recalculees ( pour des raisons de temps de calcul, et
du fait que lors des modif de pistes, les pads ne sont pas touches
*/
{
TRACK * Track;
/* Les pointeurs .start et .end sont mis a jour, si la
connexion est du type segment a segment.
la connexion sur pads est supposee etre deja calculee */
/* Raz des pointeurs sur pistes */
for( Track = pt_start_conn; Track != NULL; Track = (TRACK*) Track->Pnext)
{
Track->m_Sous_Netcode = 0;
if( Track->GetState(BEGIN_ONPAD) == 0 ) Track->start = NULL;
if( Track->GetState(END_ONPAD) == 0 ) Track->end = NULL;
if (Track == pt_end_conn) break;
}
/* calcul des connexions */
for( Track = pt_start_conn; Track != NULL; Track = (TRACK*) Track->Pnext)
{
if(Track->m_StructType == TYPEVIA)
{
TRACK* pt_segm;
int layermask = Track->ReturnMaskLayer();
for( pt_segm = pt_start_conn; pt_segm != NULL; pt_segm = (TRACK*) pt_segm->Pnext)
{
int curlayermask = pt_segm->ReturnMaskLayer();
if( (pt_segm->m_Start.x == Track->m_Start.x) &&
(pt_segm->m_Start.y == Track->m_Start.y) && ( layermask & curlayermask ) )
{
pt_segm->start = Track;
}
if( (pt_segm->m_End.x == Track->m_Start.x) &&
(pt_segm->m_End.y == Track->m_Start.y) && (layermask & curlayermask) )
{
pt_segm->end = Track;
}
if( pt_segm == pt_end_conn ) break;
}
}
if( Track->start == NULL )
{
Track->start = Locate_Piste_Connectee(Track,
Track,pt_end_conn,START);
}
if( Track->end == NULL )
{
Track->end = Locate_Piste_Connectee(Track,
Track,pt_end_conn,END);
}
if (Track == pt_end_conn) break;
}
/* Generation des sous equipots du net */
propage_equipot(pt_start_conn,pt_end_conn);
}
bool DRC::doTrackDrc( TRACK* aRefSeg, TRACK* aStart, bool testPads )
{
TRACK* track;
wxPoint delta; // lenght on X and Y axis of segments
int layerMask;
int net_code_ref;
wxPoint shape_pos;
NETCLASS* netclass = aRefSeg->GetNetClass();
/* In order to make some calculations more easier or faster,
* pads and tracks coordinates will be made relative to the reference segment origin
*/
wxPoint origin = aRefSeg->GetStart(); // origin will be the origin of other coordinates
m_segmEnd = delta = aRefSeg->GetEnd() - origin;
m_segmAngle = 0;
layerMask = aRefSeg->ReturnMaskLayer();
net_code_ref = aRefSeg->GetNet();
// Phase 0 : Test vias
if( aRefSeg->Type() == PCB_VIA_T )
{
// test if the via size is smaller than minimum
if( aRefSeg->GetShape() == VIA_MICROVIA )
{
if( aRefSeg->GetWidth() < netclass->GetuViaMinDiameter() )
{
m_currentMarker = fillMarker( aRefSeg, NULL,
DRCE_TOO_SMALL_MICROVIA, m_currentMarker );
return false;
}
}
else
{
if( aRefSeg->GetWidth() < netclass->GetViaMinDiameter() )
{
m_currentMarker = fillMarker( aRefSeg, NULL,
DRCE_TOO_SMALL_VIA, m_currentMarker );
return false;
}
}
// test if via's hole is bigger than its diameter
// This test is necessary since the via hole size and width can be modified
// and a default via hole can be bigger than some vias sizes
if( aRefSeg->GetDrillValue() > aRefSeg->GetWidth() )
{
m_currentMarker = fillMarker( aRefSeg, NULL,
DRCE_VIA_HOLE_BIGGER, m_currentMarker );
return false;
}
// For microvias: test if they are blind vias and only between 2 layers
// because they are used for very small drill size and are drill by laser
// and **only one layer** can be drilled
if( aRefSeg->GetShape() == VIA_MICROVIA )
{
int layer1, layer2;
bool err = true;
( (SEGVIA*) aRefSeg )->ReturnLayerPair( &layer1, &layer2 );
if( layer1 > layer2 )
EXCHG( layer1, layer2 );
// test:
if( layer1 == LAYER_N_BACK && layer2 == LAYER_N_2 )
err = false;
if( layer1 == (m_pcb->GetDesignSettings().GetCopperLayerCount() - 2 )
&& layer2 == LAYER_N_FRONT )
err = false;
if( err )
{
m_currentMarker = fillMarker( aRefSeg, NULL,
DRCE_MICRO_VIA_INCORRECT_LAYER_PAIR, m_currentMarker );
return false;
}
}
}
else // This is a track segment
{
if( aRefSeg->GetWidth() < netclass->GetTrackMinWidth() )
{
m_currentMarker = fillMarker( aRefSeg, NULL,
DRCE_TOO_SMALL_TRACK_WIDTH, m_currentMarker );
return false;
}
}
// for a non horizontal or vertical segment Compute the segment angle
// in tenths of degrees and its length
if( delta.x || delta.y )
{
// Compute the segment angle in 0,1 degrees
m_segmAngle = ArcTangente( delta.y, delta.x );
// Compute the segment length: we build an equivalent rotated segment,
// this segment is horizontal, therefore dx = length
RotatePoint( &delta, m_segmAngle ); // delta.x = length, delta.y = 0
}
m_segmLength = delta.x;
/******************************************/
/* Phase 1 : test DRC track to pads : */
/******************************************/
/* Use a dummy pad to test DRC tracks versus holes, for pads not on all copper layers
* but having a hole
* This dummy pad has the size and shape of the hole
* to test tracks to pad hole DRC, using checkClearanceSegmToPad test function.
* Therefore, this dummy pad is a circle or an oval.
* A pad must have a parent because some functions expect a non null parent
* to find the parent board, and some other data
*/
MODULE dummymodule( m_pcb ); // Creates a dummy parent
D_PAD dummypad( &dummymodule );
dummypad.SetLayerMask( ALL_CU_LAYERS ); // Ensure the hole is on all layers
// Compute the min distance to pads
if( testPads )
{
for( unsigned ii = 0; ii<m_pcb->GetPadCount(); ++ii )
{
D_PAD* pad = m_pcb->GetPad( ii );
/* No problem if pads are on an other layer,
* But if a drill hole exists (a pad on a single layer can have a hole!)
* we must test the hole
*/
if( (pad->GetLayerMask() & layerMask ) == 0 )
{
/* We must test the pad hole. In order to use the function
* checkClearanceSegmToPad(),a pseudo pad is used, with a shape and a
* size like the hole
*/
if( pad->GetDrillSize().x == 0 )
continue;
dummypad.SetSize( pad->GetDrillSize() );
dummypad.SetPosition( pad->GetPosition() );
dummypad.SetShape( pad->GetDrillShape() );
dummypad.SetOrientation( pad->GetOrientation() );
m_padToTestPos = dummypad.GetPosition() - origin;
if( !checkClearanceSegmToPad( &dummypad, aRefSeg->GetWidth(),
netclass->GetClearance() ) )
{
m_currentMarker = fillMarker( aRefSeg, pad,
DRCE_TRACK_NEAR_THROUGH_HOLE, m_currentMarker );
return false;
}
continue;
}
// The pad must be in a net (i.e pt_pad->GetNet() != 0 )
// but no problem if the pad netcode is the current netcode (same net)
if( pad->GetNet() // the pad must be connected
&& net_code_ref == pad->GetNet() ) // the pad net is the same as current net -> Ok
continue;
// DRC for the pad
shape_pos = pad->ReturnShapePos();
m_padToTestPos = shape_pos - origin;
if( !checkClearanceSegmToPad( pad, aRefSeg->GetWidth(), aRefSeg->GetClearance( pad ) ) )
{
m_currentMarker = fillMarker( aRefSeg, pad,
DRCE_TRACK_NEAR_PAD, m_currentMarker );
return false;
}
}
}
/***********************************************/
/* Phase 2: test DRC with other track segments */
/***********************************************/
// At this point the reference segment is the X axis
// Test the reference segment with other track segments
wxPoint segStartPoint;
wxPoint segEndPoint;
for( track = aStart; track; track = track->Next() )
{
// No problem if segments have the same net code:
if( net_code_ref == track->GetNet() )
continue;
// No problem if segment are on different layers :
if( ( layerMask & track->ReturnMaskLayer() ) == 0 )
continue;
// the minimum distance = clearance plus half the reference track
// width plus half the other track's width
int w_dist = aRefSeg->GetClearance( track );
w_dist += (aRefSeg->GetWidth() + track->GetWidth()) / 2;
// If the reference segment is a via, we test it here
if( aRefSeg->Type() == PCB_VIA_T )
{
int angle = 0; // angle du segment a tester;
delta = track->GetEnd() - track->GetStart();
segStartPoint = aRefSeg->GetStart() - track->GetStart();
if( track->Type() == PCB_VIA_T )
{
// Test distance between two vias, i.e. two circles, trivial case
if( (int) hypot( segStartPoint.x, segStartPoint.y ) < w_dist )
{
m_currentMarker = fillMarker( aRefSeg, track,
DRCE_VIA_NEAR_VIA, m_currentMarker );
return false;
}
}
else // test via to segment
{
// Compute l'angle
angle = ArcTangente( delta.y, delta.x );
// Compute new coordinates ( the segment become horizontal)
RotatePoint( &delta, angle );
RotatePoint( &segStartPoint, angle );
if( !checkMarginToCircle( segStartPoint, w_dist, delta.x ) )
{
m_currentMarker = fillMarker( track, aRefSeg,
DRCE_VIA_NEAR_TRACK, m_currentMarker );
return false;
}
}
continue;
}
/* We compute segStartPoint, segEndPoint = starting and ending point coordinates for
* the segment to test in the new axis : the new X axis is the
* reference segment. We must translate and rotate the segment to test
*/
segStartPoint = track->GetStart() - origin;
segEndPoint = track->GetEnd() - origin;
RotatePoint( &segStartPoint, m_segmAngle );
RotatePoint( &segEndPoint, m_segmAngle );
if( track->Type() == PCB_VIA_T )
{
if( checkMarginToCircle( segStartPoint, w_dist, m_segmLength ) )
continue;
m_currentMarker = fillMarker( aRefSeg, track,
DRCE_TRACK_NEAR_VIA, m_currentMarker );
return false;
}
/* We have changed axis:
* the reference segment is Horizontal.
* 3 cases : the segment to test can be parallel, perpendicular or have an other direction
*/
if( segStartPoint.y == segEndPoint.y ) // parallel segments
{
if( abs( segStartPoint.y ) >= w_dist )
continue;
// Ensure segStartPoint.x <= segEndPoint.x
if( segStartPoint.x > segEndPoint.x )
EXCHG( segStartPoint.x, segEndPoint.x );
if( segStartPoint.x > (-w_dist) && segStartPoint.x < (m_segmLength + w_dist) ) /* possible error drc */
{
// Fine test : we consider the rounded shape of each end of the track segment:
if( segStartPoint.x >= 0 && segStartPoint.x <= m_segmLength )
{
m_currentMarker = fillMarker( aRefSeg, track,
DRCE_TRACK_ENDS1, m_currentMarker );
return false;
}
if( !checkMarginToCircle( segStartPoint, w_dist, m_segmLength ) )
{
m_currentMarker = fillMarker( aRefSeg, track,
DRCE_TRACK_ENDS2, m_currentMarker );
return false;
}
}
if( segEndPoint.x > (-w_dist) && segEndPoint.x < (m_segmLength + w_dist) )
{
/* Fine test : we consider the rounded shape of the ends */
if( segEndPoint.x >= 0 && segEndPoint.x <= m_segmLength )
{
m_currentMarker = fillMarker( aRefSeg, track,
DRCE_TRACK_ENDS3, m_currentMarker );
return false;
}
if( !checkMarginToCircle( segEndPoint, w_dist, m_segmLength ) )
{
m_currentMarker = fillMarker( aRefSeg, track,
DRCE_TRACK_ENDS4, m_currentMarker );
return false;
}
}
if( segStartPoint.x <=0 && segEndPoint.x >= 0 )
{
m_currentMarker = fillMarker( aRefSeg, track,
DRCE_TRACK_UNKNOWN1, m_currentMarker );
return false;
}
}
else if( segStartPoint.x == segEndPoint.x ) // perpendicular segments
{
if( ( segStartPoint.x <= (-w_dist) ) || ( segStartPoint.x >= (m_segmLength + w_dist) ) )
continue;
// Test if segments are crossing
if( segStartPoint.y > segEndPoint.y )
EXCHG( segStartPoint.y, segEndPoint.y );
if( (segStartPoint.y < 0) && (segEndPoint.y > 0) )
{
m_currentMarker = fillMarker( aRefSeg, track,
DRCE_TRACKS_CROSSING, m_currentMarker );
return false;
}
// At this point the drc error is due to an end near a reference segm end
if( !checkMarginToCircle( segStartPoint, w_dist, m_segmLength ) )
{
m_currentMarker = fillMarker( aRefSeg, track,
DRCE_ENDS_PROBLEM1, m_currentMarker );
return false;
}
if( !checkMarginToCircle( segEndPoint, w_dist, m_segmLength ) )
{
m_currentMarker = fillMarker( aRefSeg, track,
DRCE_ENDS_PROBLEM2, m_currentMarker );
return false;
}
}
else // segments quelconques entre eux
{
// calcul de la "surface de securite du segment de reference
// First rought 'and fast) test : the track segment is like a rectangle
m_xcliplo = m_ycliplo = -w_dist;
m_xcliphi = m_segmLength + w_dist;
m_ycliphi = w_dist;
// A fine test is needed because a serment is not exactly a
// rectangle, it has rounded ends
if( !checkLine( segStartPoint, segEndPoint ) )
{
/* 2eme passe : the track has rounded ends.
* we must a fine test for each rounded end and the
* rectangular zone
*/
m_xcliplo = 0;
m_xcliphi = m_segmLength;
if( !checkLine( segStartPoint, segEndPoint ) )
{
m_currentMarker = fillMarker( aRefSeg, track,
DRCE_ENDS_PROBLEM3, m_currentMarker );
return false;
}
else // The drc error is due to the starting or the ending point of the reference segment
{
// Test the starting and the ending point
segStartPoint = track->GetStart();
segEndPoint = track->GetEnd();
delta = segEndPoint - segStartPoint;
/* Compute the segment orientation (angle) en 0,1 degre */
int angle = ArcTangente( delta.y, delta.x );
// Compute the segment lenght: delta.x = lenght after rotation
RotatePoint( &delta, angle );
/* Comute the reference segment coordinates relatives to a
* X axis = current tested segment
*/
wxPoint relStartPos = aRefSeg->GetStart() - segStartPoint;
wxPoint relEndPos = aRefSeg->GetEnd() - segStartPoint;
RotatePoint( &relStartPos, angle );
RotatePoint( &relEndPos, angle );
if( !checkMarginToCircle( relStartPos, w_dist, delta.x ) )
{
m_currentMarker = fillMarker( aRefSeg, track,
DRCE_ENDS_PROBLEM4, m_currentMarker );
return false;
}
if( !checkMarginToCircle( relEndPos, w_dist, delta.x ) )
{
m_currentMarker = fillMarker( aRefSeg, track,
DRCE_ENDS_PROBLEM5, m_currentMarker );
return false;
}
}
}
}
}
return true;
}
