Ejemplo n.º 1
0
bool TRACKS_CLEANER::remove_duplicates_of_track( const TRACK *aTrack )
{
    bool modified = false;

    TRACK *nextsegment;
    for( TRACK *other = aTrack->Next(); other; other = nextsegment )
    {
        nextsegment = other->Next();

        // New netcode, break out (can't be there any other)
        if( aTrack->GetNetCode() != other->GetNetCode() )
            break;

        // Must be of the same type, on the same layer and the endpoints
        // must be the same (maybe swapped)
        if( (aTrack->Type() != other->Type()) &&
            (aTrack->GetLayer() != other->GetLayer()) )
        {
            if( ((aTrack->GetStart() == other->GetStart()) &&
                 (aTrack->GetEnd() == other->GetEnd())) ||
                ((aTrack->GetStart() == other->GetEnd()) &&
                 (aTrack->GetEnd() == other->GetStart())))
            {
                m_Brd->GetRatsnest()->Remove( other );
                other->ViewRelease();
                other->DeleteStructure();
                modified = true;
            }
        }
    }
    return modified;
}
Ejemplo n.º 2
0
static void export_vrml_tracks( BOARD* pcb ) //{{{
{
    for( TRACK* track = pcb->m_Track; track != NULL; track = track->Next() )
    {
        if( track->Type() == PCB_VIA_T )
            export_vrml_via( pcb, (SEGVIA*) track );
        else
            export_vrml_line( track->GetLayer(), track->GetStart().x, track->GetStart().y,
                              track->GetEnd().x, track->GetEnd().y, track->GetWidth(), 4 );
    }
}
Ejemplo n.º 3
0
void ROUTER_TOOL::NeighboringSegmentFilter( const VECTOR2I& aPt, GENERAL_COLLECTOR& aCollector )
{
    /*
     * If the collection contains a trivial line corner (two connected segments)
     * or a non-fanout-via (a via with no more than two connected segments), then
     * trim the collection down to a single item (which one won't matter since
     * they're all connected).
     */

    // First make sure we've got something that *might* match.
    int vias = aCollector.CountType( PCB_VIA_T );
    int traces = aCollector.CountType( PCB_TRACE_T );

    if( vias > 1 || traces > 2 || vias + traces < 1 )
        return;

    // Fetch first TRACK (via or trace) as our reference
    TRACK* reference = nullptr;

    for( int i = 0; !reference && i < aCollector.GetCount(); i++ )
        reference = dynamic_cast<TRACK*>( aCollector[i] );

    int refNet = reference->GetNetCode();

    wxPoint refPoint( aPt.x, aPt.y );
    STATUS_FLAGS flags = reference->IsPointOnEnds( refPoint, -1 );

    if( flags & STARTPOINT )
        refPoint = reference->GetStart();
    else if( flags & ENDPOINT )
        refPoint = reference->GetEnd();

    // Check all items to ensure that any TRACKs are co-terminus with the reference and on
    // the same net.
    for( int i = 0; i < aCollector.GetCount(); i++ )
    {
        TRACK* neighbor = dynamic_cast<TRACK*>( aCollector[i] );

        if( neighbor && neighbor != reference )
        {
            if( neighbor->GetNetCode() != refNet )
                return;

            if( neighbor->GetStart() != refPoint && neighbor->GetEnd() != refPoint )
                return;
        }
    }

    // Selection meets criteria; trim it to the reference item.
    aCollector.Empty();
    aCollector.Append( reference );
}
Ejemplo n.º 4
0
TRACK* GetTrack( TRACK* aStartTrace, const TRACK* aEndTrace,
        const wxPoint& aPosition, LAYER_MSK aLayerMask )
{
    for( TRACK *PtSegm = aStartTrace; PtSegm != NULL; PtSegm = PtSegm->Next() )
    {
        if( PtSegm->GetState( IS_DELETED | BUSY ) == 0 )
        {
            if( aPosition == PtSegm->GetStart() )
            {
                if( aLayerMask & PtSegm->GetLayerMask() )
                    return PtSegm;
            }

            if( aPosition == PtSegm->GetEnd() )
            {
                if( aLayerMask & PtSegm->GetLayerMask() )
                    return PtSegm;
            }
        }

        if( PtSegm == aEndTrace )
            break;
    }

    return NULL;
}
Ejemplo n.º 5
0
TRACK* GetTrack( TRACK* aStartTrace, const TRACK* aEndTrace,
        const wxPoint& aPosition, LSET aLayerMask )
{
    for( TRACK* seg = aStartTrace;  seg;  seg = seg->Next() )
    {
        if( seg->GetState( IS_DELETED | BUSY ) == 0 )
        {
            if( aPosition == seg->GetStart() )
            {
                if( ( aLayerMask & seg->GetLayerSet() ).any() )
                    return seg;
            }

            if( aPosition == seg->GetEnd() )
            {
                if( ( aLayerMask & seg->GetLayerSet() ).any() )
                    return seg;
            }
        }

        if( seg == aEndTrace )
            break;
    }

    return NULL;
}
Ejemplo n.º 6
0
// Redraw the moved node according to the mouse cursor position
static void Show_MoveNode( EDA_DRAW_PANEL* aPanel, wxDC* aDC, const wxPoint& aPosition,
                           bool aErase )
{
    auto displ_opts = (PCB_DISPLAY_OPTIONS*) aPanel->GetDisplayOptions();
    wxPoint      moveVector;
    int          tmp = displ_opts->m_DisplayPcbTrackFill;
    GR_DRAWMODE  draw_mode = GR_XOR | GR_HIGHLIGHT;

    displ_opts->m_DisplayPcbTrackFill = false;

#ifndef USE_WX_OVERLAY
    aErase = true;
#else
    aErase = false;
#endif

    // set the new track coordinates
    wxPoint Pos = aPanel->GetParent()->GetCrossHairPosition();

    moveVector = Pos - s_LastPos;
    s_LastPos  = Pos;

    TRACK *track = NULL;

    for( unsigned ii = 0; ii < g_DragSegmentList.size(); ii++ )
    {
        track = g_DragSegmentList[ii].m_Track;

        if( aErase )
            track->Draw( aPanel, aDC, draw_mode );

        if( track->GetFlags() & STARTPOINT )
            track->SetStart( track->GetStart() + moveVector );

        if( track->GetFlags() & ENDPOINT )
            track->SetEnd( track->GetEnd() + moveVector );

        if( track->Type() == PCB_VIA_T )
            track->SetEnd( track->GetStart() );

        track->Draw( aPanel, aDC, draw_mode );
    }

    displ_opts->m_DisplayPcbTrackFill = tmp;

    // Display track length
    if( track )
    {
        PCB_BASE_FRAME* frame = (PCB_BASE_FRAME*) aPanel->GetParent();
        frame->SetMsgPanel( track );
    }
}
Ejemplo n.º 7
0
void DRC::testKeepoutAreas()
{
    // Test keepout areas for vias, tracks and pads inside keepout areas
    for( int ii = 0; ii < m_pcb->GetAreaCount(); ii++ )
    {
        ZONE_CONTAINER* area = m_pcb->GetArea( ii );

        if( !area->GetIsKeepout() )
            continue;

        for( TRACK* segm = m_pcb->m_Track; segm != NULL; segm = segm->Next() )
        {
            if( segm->Type() == PCB_TRACE_T )
            {
                if( ! area->GetDoNotAllowTracks()  )
                    continue;

                if( segm->GetLayer() != area->GetLayer() )
                    continue;

                if( area->Outline()->Distance( segm->GetStart(), segm->GetEnd(),
                                               segm->GetWidth() ) == 0 )
                {
                    m_currentMarker = fillMarker( segm, NULL,
                                                  DRCE_TRACK_INSIDE_KEEPOUT, m_currentMarker );
                    m_pcb->Add( m_currentMarker );
                    m_mainWindow->GetGalCanvas()->GetView()->Add( m_currentMarker );
                    m_currentMarker = 0;
                }
            }
            else if( segm->Type() == PCB_VIA_T )
            {
                if( ! area->GetDoNotAllowVias()  )
                    continue;

                if( ! ((VIA*)segm)->IsOnLayer( area->GetLayer() ) )
                    continue;

                if( area->Outline()->Distance( segm->GetPosition() ) < segm->GetWidth()/2 )
                {
                    m_currentMarker = fillMarker( segm, NULL,
                                                  DRCE_VIA_INSIDE_KEEPOUT, m_currentMarker );
                    m_pcb->Add( m_currentMarker );
                    m_mainWindow->GetGalCanvas()->GetView()->Add( m_currentMarker );
                    m_currentMarker = 0;
                }
            }
        }
        // Test pads: TODO
    }
}
Ejemplo n.º 8
0
static void export_vrml_tracks( MODEL_VRML& aModel, BOARD* pcb )
{
    for( TRACK* track = pcb->m_Track; track; track = track->Next() )
    {
        if( track->Type() == PCB_VIA_T )
        {
            export_vrml_via( aModel, pcb, (const VIA*) track );
        }
        else if( track->GetLayer() == B_Cu || track->GetLayer() == F_Cu )
            export_vrml_line( aModel, track->GetLayer(),
                    track->GetStart().x * aModel.scale,
                    track->GetStart().y * aModel.scale,
                    track->GetEnd().x * aModel.scale,
                    track->GetEnd().y * aModel.scale,
                    track->GetWidth() * aModel.scale );
    }
}
Ejemplo n.º 9
0
void CONNECTIONS::BuildTracksCandidatesList( TRACK* aBegin, TRACK* aEnd)
{
    m_candidates.clear();
    m_firstTrack = m_lastTrack = aBegin;

    unsigned ii = 0;

    // Count candidates ( i.e. end points )
    for( const TRACK* track = aBegin; track; track = track->Next() )
    {
        if( track->Type() == PCB_VIA_T )
            ii++;
        else
            ii += 2;

        m_lastTrack = track;

        if( track == aEnd )
            break;
    }

    // Build candidate list
    m_candidates.reserve( ii );
    for( TRACK* track = aBegin; track; track = track->Next() )
    {
        CONNECTED_POINT candidate( track, track->GetStart() );

        m_candidates.push_back( candidate );
        if( track->Type() != PCB_VIA_T )
        {
            CONNECTED_POINT candidate2( track, track->GetEnd());
            m_candidates.push_back( candidate2 );
        }

        if( track == aEnd )
            break;
    }

    // Sort list by increasing X coordinate,
    // and for increasing Y coordinate when items have the same X coordinate
    // So candidates to the same location are consecutive in list.
    sort( m_candidates.begin(), m_candidates.end(), sortConnectedPointByXthenYCoordinates );
}
Ejemplo n.º 10
0
void TRACKS_CLEANER::buildTrackConnectionInfo()
{
    BuildTracksCandidatesList( m_Brd->m_Track, NULL);

    // clear flags and variables used in cleanup
    for( TRACK * track = m_Brd->m_Track; track; track = track->Next() )
    {
        track->start = NULL;
        track->end = NULL;
        track->m_PadsConnected.clear();
        track->SetState( START_ON_PAD|END_ON_PAD|BUSY, false );
    }

    // Build connections info tracks to pads
    SearchTracksConnectedToPads();
    for( TRACK * track = m_Brd->m_Track; track; track = track->Next() )
    {
        // Mark track if connected to pads
        for( unsigned jj = 0; jj < track->m_PadsConnected.size(); jj++ )
        {
            D_PAD * pad = track->m_PadsConnected[jj];

            if( pad->HitTest( track->GetStart() ) )
            {
                track->start = pad;
                track->SetState( START_ON_PAD, true );
            }

            if( pad->HitTest( track->GetEnd() ) )
            {
                track->end = pad;
                track->SetState( END_ON_PAD, true );
            }
        }
    }
}
Ejemplo n.º 11
0
void DRC::testTexts()
{
    std::vector<wxPoint> textShape;      // a buffer to store the text shape (set of segments)
    std::vector<D_PAD*> padList = m_pcb->GetPads();

    // Test text areas for vias, tracks and pads inside text areas
    for( BOARD_ITEM* item = m_pcb->m_Drawings; item; item = item->Next() )
    {
        // Drc test only items on copper layers
        if( ! IsCopperLayer( item->GetLayer() ) )
            continue;

        // only texts on copper layers are tested
        if( item->Type() !=  PCB_TEXT_T )
            continue;

        textShape.clear();

        // So far the bounding box makes up the text-area
        TEXTE_PCB* text = (TEXTE_PCB*) item;
        text->TransformTextShapeToSegmentList( textShape );

        if( textShape.size() == 0 )     // Should not happen (empty text?)
            continue;

        for( TRACK* track = m_pcb->m_Track; track != NULL; track = track->Next() )
        {
            if( ! track->IsOnLayer( item->GetLayer() ) )
                    continue;

            // Test the distance between each segment and the current track/via
            int min_dist = ( track->GetWidth() + text->GetThickness() ) /2 +
                           track->GetClearance(NULL);

            if( track->Type() == PCB_TRACE_T )
            {
                SEG segref( track->GetStart(), track->GetEnd() );

                // Error condition: Distance between text segment and track segment is
                // smaller than the clearance of the segment
                for( unsigned jj = 0; jj < textShape.size(); jj += 2 )
                {
                    SEG segtest( textShape[jj], textShape[jj+1] );
                    int dist = segref.Distance( segtest );

                    if( dist < min_dist )
                    {
                        addMarkerToPcb( fillMarker( track, text,
                                                    DRCE_TRACK_INSIDE_TEXT,
                                                    m_currentMarker ) );
                        m_currentMarker = nullptr;
                        break;
                    }
                }
            }
            else if( track->Type() == PCB_VIA_T )
            {
                // Error condition: Distance between text segment and via is
                // smaller than the clearance of the via
                for( unsigned jj = 0; jj < textShape.size(); jj += 2 )
                {
                    SEG segtest( textShape[jj], textShape[jj+1] );

                    if( segtest.PointCloserThan( track->GetPosition(), min_dist ) )
                    {
                        addMarkerToPcb( fillMarker( track, text,
                                                    DRCE_VIA_INSIDE_TEXT, m_currentMarker ) );
                        m_currentMarker = nullptr;
                        break;
                    }
                }
            }
        }

        // Test pads
        for( unsigned ii = 0; ii < padList.size(); ii++ )
        {
            D_PAD* pad = padList[ii];

            if( ! pad->IsOnLayer( item->GetLayer() ) )
                    continue;

            wxPoint shape_pos = pad->ShapePos();

            for( unsigned jj = 0; jj < textShape.size(); jj += 2 )
            {
                /* In order to make some calculations more easier or faster,
                 * pads and tracks coordinates will be made relative
                 * to the segment origin
                 */
                wxPoint origin = textShape[jj];  // origin will be the origin of other coordinates
                m_segmEnd = textShape[jj+1] - origin;
                wxPoint delta = m_segmEnd;
                m_segmAngle = 0;

                // for a non horizontal or vertical segment Compute the segment angle
                // in tenths of degrees and its length
                if( delta.x || delta.y )    // delta.x == delta.y == 0 for vias
                {
                    // 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;
                m_padToTestPos = shape_pos - origin;

                if( !checkClearanceSegmToPad( pad, text->GetThickness(),
                                              pad->GetClearance(NULL) ) )
                {
                    addMarkerToPcb( fillMarker( pad, text,
                                                DRCE_PAD_INSIDE_TEXT, m_currentMarker ) );
                    m_currentMarker = nullptr;
                    break;
                }
            }
        }
    }
}
Ejemplo n.º 12
0
/* Function BuildAirWiresTargetsList
 * Build a list of candidates that can be a coonection point
 * when a track is started.
 * This functions prepares data to show airwires to nearest connecting points (pads)
 * from the current new track to candidates during track creation
 */
void PCB_BASE_FRAME::BuildAirWiresTargetsList( BOARD_CONNECTED_ITEM* aItemRef,
                                               const wxPoint& aPosition, bool aInit )
{
    if( ( ( m_Pcb->m_Status_Pcb & LISTE_RATSNEST_ITEM_OK ) == 0 )
       || ( ( m_Pcb->m_Status_Pcb & LISTE_PAD_OK ) == 0 )
       || ( ( m_Pcb->m_Status_Pcb & NET_CODES_OK ) == 0 ) )
    {
        s_TargetsLocations.clear();
        return;
    }

    s_CursorPos = aPosition;    // needed for sort_by_distance

    if( aInit )
    {
        s_TargetsLocations.clear();

        if( aItemRef == NULL )
            return;

        int net_code = aItemRef->GetNet();
        int subnet = aItemRef->GetSubNet();

        if( net_code <= 0 )
            return;

        NETINFO_ITEM* net = m_Pcb->FindNet( net_code );

        if( net == NULL )        // Should not occur
        {
            wxMessageBox( wxT( "BuildAirWiresTargetsList() error: net not found" ) );
            return;
        }

        // Create a list of pads candidates ( pads not already connected to the
        // current track ):
        for( unsigned ii = 0; ii < net->m_PadInNetList.size(); ii++ )
        {
            D_PAD* pad = net->m_PadInNetList[ii];

            if( pad == aItemRef )
                continue;

            if( !pad->GetSubNet() || (pad->GetSubNet() != subnet) )
                s_TargetsLocations.push_back( pad->GetPosition() );
        }

        // Create a list of tracks ends candidates, not already connected to the
        // current track:
        for( TRACK* track = m_Pcb->m_Track; track; track = track->Next() )
        {
            if( track->GetNet() < net_code )
                continue;
            if( track->GetNet() > net_code )
                break;;

            if( !track->GetSubNet() || (track->GetSubNet() != subnet) )
            {
                if( aPosition != track->GetStart() )
                    s_TargetsLocations.push_back( track->GetStart() );
                if( aPosition != track->GetEnd() && track->GetStart() != track->GetEnd() )
                    s_TargetsLocations.push_back( track->GetEnd() );
            }
        }

        // Remove duplicate targets, using the C++ unique algorithm
        sort( s_TargetsLocations.begin(), s_TargetsLocations.end(), sort_by_point );
        std::vector< wxPoint >::iterator it = unique( s_TargetsLocations.begin(), s_TargetsLocations.end() );

        // Using the C++ unique algorithm only moves the duplicate entries to the end of
        // of the array.  This removes the duplicate entries from the array.
        s_TargetsLocations.resize( it - s_TargetsLocations.begin() );
    }   // end if Init

    // in all cases, sort by distances:
    sort( s_TargetsLocations.begin(), s_TargetsLocations.end(), sort_by_distance );
}
bool DRC::doTrackDrc( TRACK* aRefSeg, TRACK* aStart, bool testPads )
{
    TRACK*    track;
    wxPoint   delta;           // length on X and Y axis of segments
    LSET layerMask;
    int       net_code_ref;
    wxPoint   shape_pos;

    NETCLASSPTR netclass = aRefSeg->GetNetClass();
    BOARD_DESIGN_SETTINGS& dsnSettings = m_pcb->GetDesignSettings();

    /* 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->GetLayerSet();
    net_code_ref = aRefSeg->GetNetCode();

    // Phase 0 : Test vias
    if( aRefSeg->Type() == PCB_VIA_T )
    {
        const VIA *refvia = static_cast<const VIA*>( aRefSeg );
        // test if the via size is smaller than minimum
        if( refvia->GetViaType() == VIA_MICROVIA )
        {
            if( refvia->GetWidth() < dsnSettings.m_MicroViasMinSize )
            {
                m_currentMarker = fillMarker( refvia, NULL,
                                              DRCE_TOO_SMALL_MICROVIA, m_currentMarker );
                return false;
            }
            if( refvia->GetDrillValue() < dsnSettings.m_MicroViasMinDrill )
            {
                m_currentMarker = fillMarker( refvia, NULL,
                                              DRCE_TOO_SMALL_MICROVIA_DRILL, m_currentMarker );
                return false;
            }
        }
        else
        {
            if( refvia->GetWidth() < dsnSettings.m_ViasMinSize )
            {
                m_currentMarker = fillMarker( refvia, NULL,
                                              DRCE_TOO_SMALL_VIA, m_currentMarker );
                return false;
            }
            if( refvia->GetDrillValue() < dsnSettings.m_ViasMinDrill )
            {
                m_currentMarker = fillMarker( refvia, NULL,
                                              DRCE_TOO_SMALL_VIA_DRILL, 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( refvia->GetDrillValue() > refvia->GetWidth() )
        {
            m_currentMarker = fillMarker( refvia, 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( refvia->GetViaType() == VIA_MICROVIA )
        {
            LAYER_ID    layer1, layer2;
            bool        err = true;

            refvia->LayerPair( &layer1, &layer2 );

            if( layer1 > layer2 )
                std::swap( layer1, layer2 );

            if( layer2 == B_Cu && layer1 == m_pcb->GetDesignSettings().GetCopperLayerCount() - 2 )
                err = false;
            else if( layer1 == F_Cu  &&  layer2 == In1_Cu  )
                err = false;

            if( err )
            {
                m_currentMarker = fillMarker( refvia, NULL,
                                              DRCE_MICRO_VIA_INCORRECT_LAYER_PAIR, m_currentMarker );
                return false;
            }
        }
    }
    else    // This is a track segment
    {
        if( aRefSeg->GetWidth() < dsnSettings.m_TrackMinWidth )
        {
            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.SetLayerSet( LSET::AllCuMask() );     // Ensure the hole is on all layers

    // Compute the min distance to pads
    if( testPads )
    {
        unsigned pad_count = m_pcb->GetPadCount();

        for( unsigned ii = 0;  ii<pad_count;  ++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->GetLayerSet() & layerMask ).any() )
            {
                /* 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()  == PAD_DRILL_SHAPE_OBLONG ?
                                   PAD_SHAPE_OVAL : PAD_SHAPE_CIRCLE );
                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->GetNetCode()                       // the pad must be connected
               && net_code_ref == pad->GetNetCode() )   // the pad net is the same as current net -> Ok
                continue;

            // DRC for the pad
            shape_pos = pad->ShapePos();
            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->GetNetCode() )
            continue;

        // No problem if segment are on different layers :
        if( !( layerMask & track->GetLayerSet() ).any() )
            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;

        // Due to many double to int conversions during calculations, which
        // create rounding issues,
        // the exact clearance margin cannot be really known.
        // To avoid false bad DRC detection due to these rounding issues,
        // slightly decrease the w_dist (remove one nanometer is enough !)
        w_dist -= 1;

        // If the reference segment is a via, we test it here
        if( aRefSeg->Type() == PCB_VIA_T )
        {
            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( EuclideanNorm( segStartPoint ) < w_dist )
                {
                    m_currentMarker = fillMarker( aRefSeg, track,
                                                  DRCE_VIA_NEAR_VIA, m_currentMarker );
                    return false;
                }
            }
            else    // test via to segment
            {
                // Compute l'angle du segment a tester;
                double 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 )
                std::swap( segStartPoint.x, segEndPoint.x );

            if( segStartPoint.x > (-w_dist) && segStartPoint.x < (m_segmLength + w_dist) )    /* possible error drc */
            {
                // the start point is inside the reference range
                //      X........
                //    O--REF--+

                // 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) )
            {
                // the end point is inside the reference range
                //  .....X
                //    O--REF--+
                // 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 )
            {
            // the segment straddles the reference range (this actually only
            // checks if it straddles the origin, because the other cases where already
            // handled)
            //  X.............X
            //    O--REF--+
                m_currentMarker = fillMarker( aRefSeg, track,
                                              DRCE_TRACK_SEGMENTS_TOO_CLOSE, 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 )
                std::swap( 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
                    double angle = ArcTangente( delta.y, delta.x );

                    // Compute the segment length: delta.x = length 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;
}
/**
 * Function Magnetize
 * tests to see if there are any magnetic items within near reach of the given
 * "curpos".  If yes, then curpos is adjusted appropriately according to that
 * near magnetic item and true is returned.
 * @param frame = the current frame
 * @param aCurrentTool = the current tool id (from vertical right toolbar)
 * @param aGridSize = the current grid size
 * @param on_grid = the on grid position near initial position ( often on_grid = curpos)
 * @param curpos The initial position, and what to adjust if a change is needed.
 * @return bool - true if the position was adjusted magnetically, else false.
 */
bool Magnetize( PCB_EDIT_FRAME* frame, int aCurrentTool, wxSize aGridSize,
                wxPoint on_grid, wxPoint* curpos )
{
    bool    doCheckNet = g_MagneticPadOption != capture_always && g_Drc_On;
    bool    doTrack = false;
    bool    doPad = false;
    bool    amMovingVia = false;

    BOARD* m_Pcb = frame->GetBoard();
    TRACK*      currTrack = g_CurrentTrackSegment;
    BOARD_ITEM* currItem  = frame->GetCurItem();
    PCB_SCREEN* screen = frame->GetScreen();
    wxPoint     pos = frame->RefPos( true );

    // D( printf( "currTrack=%p currItem=%p currTrack->Type()=%d currItem->Type()=%d\n",  currTrack, currItem, currTrack ? currTrack->Type() : 0, currItem ? currItem->Type() : 0 ); )

    if( !currTrack && currItem && currItem->Type()==PCB_VIA_T && currItem->GetFlags() )
    {
        // moving a VIA
        currTrack = (TRACK*) currItem;
        amMovingVia = true;

        return false;   // comment this return out and play with it.
    }
    else if( currItem != currTrack )
    {
        currTrack = NULL;
    }

    if( g_MagneticPadOption == capture_always )
        doPad = true;

    if( g_MagneticTrackOption == capture_always )
        doTrack = true;

    if( aCurrentTool == ID_TRACK_BUTT || amMovingVia )
    {
        int q = capture_cursor_in_track_tool;

        if( g_MagneticPadOption == q )
            doPad = true;

        if( g_MagneticTrackOption == q )
            doTrack = true;
    }

    // D(printf("doPad=%d doTrack=%d aCurrentTool=%d amMovingVia=%d\n", doPad, doTrack, aCurrentTool, amMovingVia );)

    //  The search precedence order is pads, then tracks/vias

    if( doPad )
    {
        LSET    layer_mask( screen->m_Active_Layer );
        D_PAD*  pad = m_Pcb->GetPad( pos, layer_mask );

        if( pad )
        {
            if( doCheckNet && currTrack && currTrack->GetNetCode() != pad->GetNetCode() )
                return false;

            *curpos = pad->GetPosition();
            return true;
        }
    }

    // after pads, only track & via tests remain, skip them if not desired
    if( doTrack )
    {
        LAYER_ID layer = screen->m_Active_Layer;

        for( TRACK* via = m_Pcb->m_Track;
                via && (via = via->GetVia( *curpos, layer )) != NULL;
                via = via->Next() )
        {
            if( via != currTrack )   // a via cannot influence itself
            {
                if( !doCheckNet || !currTrack || currTrack->GetNetCode() == via->GetNetCode() )
                {
                    *curpos = via->GetStart();
                    // D(printf("via hit\n");)
                    return true;
                }
            }
        }

        if( !currTrack )
        {
            LSET layers( layer );

            TRACK* track = m_Pcb->GetVisibleTrack( m_Pcb->m_Track, pos, layers );

            if( !track || track->Type() != PCB_TRACE_T )
            {
                // D(printf("!currTrack and track=%p not found, layer_mask=0x%X\n", track, layer_mask );)
                return false;
            }

            // D( printf( "Project\n" ); )
            return Project( curpos, on_grid, track );
        }

        /*
         * In two segment mode, ignore the final segment if it's inside a grid square.
         */
        if( !amMovingVia && currTrack && g_TwoSegmentTrackBuild && currTrack->Back()
            && currTrack->GetStart().x - aGridSize.x < currTrack->GetEnd().x
            && currTrack->GetStart().x + aGridSize.x > currTrack->GetEnd().x
            && currTrack->GetStart().y - aGridSize.y < currTrack->GetEnd().y
            && currTrack->GetStart().y + aGridSize.y > currTrack->GetEnd().y )
        {
            currTrack = currTrack->Back();
        }


        for( TRACK* track = m_Pcb->m_Track; track; track = track->Next() )
        {
            if( track->Type() != PCB_TRACE_T )
                continue;

            if( doCheckNet && currTrack && currTrack->GetNetCode() != track->GetNetCode() )
                continue;

            if( m_Pcb->IsLayerVisible( track->GetLayer() ) == false )
                continue;

            // omit the layer check if moving a via
            if( !amMovingVia && !track->IsOnLayer( layer ) )
                continue;

            if( !track->HitTest( *curpos ) )
                continue;

            // D(printf( "have track prospect\n");)

            if( Join( curpos, track->GetStart(), track->GetEnd(), currTrack->GetStart(), currTrack->GetEnd() ) )
            {
                // D(printf( "join currTrack->Type()=%d\n", currTrack->Type() );)
                return true;
            }

            if( aCurrentTool == ID_TRACK_BUTT || amMovingVia )
            {
                // At this point we have a drawing mouse on a track, we are drawing
                // a new track and that new track is parallel to the track the
                // mouse is on. Find the nearest end point of the track under mouse
                // to the mouse and return that.
                double distStart = GetLineLength( *curpos, track->GetStart() );
                double distEnd   = GetLineLength( *curpos, track->GetEnd() );

                // if track not via, or if its a via dragging but not with its adjacent track
                if( currTrack->Type() != PCB_VIA_T ||
                    ( currTrack->GetStart() != track->GetStart() && currTrack->GetStart() != track->GetEnd() ))
                {
                    double max_dist = currTrack->GetWidth() / 2.0f;

                    if( distStart <= max_dist )
                    {
                        // D(printf("nearest end is start\n");)
                        *curpos = track->GetStart();
                        return true;
                    }

                    if( distEnd <= max_dist )
                    {
                        // D(printf("nearest end is end\n");)
                        *curpos = track->GetEnd();
                        return true;
                    }

                    // @todo otherwise confine curpos such that it stays centered within "track"
                }
            }
        }
    }

    return false;
}
Ejemplo n.º 15
0
// Delete null length segments, and intermediate points ..
bool TRACKS_CLEANER::clean_segments()
{
    bool modified = false;
    TRACK*          segment, * nextsegment;
    TRACK*          other;
    int             flag, no_inc;


    // Delete null segments
    for( segment = m_Brd->m_Track; segment; segment = nextsegment )
    {
        nextsegment = segment->Next();

        if( segment->IsNull() )     // Length segment = 0; delete it
            segment->DeleteStructure();
    }

    // Delete redundant segments, i.e. segments having the same end points
    // and layers
    for( segment  = m_Brd->m_Track; segment; segment = segment->Next() )
    {
        for( other = segment->Next(); other; other = nextsegment )
        {
            nextsegment = other->Next();
            bool erase = false;

            if( segment->Type() != other->Type() )
                continue;

            if( segment->GetLayer() != other->GetLayer() )
                continue;

            if( segment->GetNetCode() != other->GetNetCode() )
                break;

            if( ( segment->GetStart() == other->GetStart() ) &&
                ( segment->GetEnd() == other->GetEnd() ) )
                erase = true;

            if( ( segment->GetStart() == other->GetEnd() ) &&
                ( segment->GetEnd() == other->GetStart() ) )
                erase = true;

            // Delete redundant point
            if( erase )
            {
                other->DeleteStructure();
                modified = true;
            }
        }
    }

    // merge collinear segments:
    for( segment = m_Brd->m_Track; segment; segment = nextsegment )
    {
        TRACK*  segStart;
        TRACK*  segEnd;
        TRACK*  segDelete;

        nextsegment = segment->Next();

        if( segment->Type() != PCB_TRACE_T )
            continue;

        flag = no_inc = 0;

        // search for a possible point connected to the START point of the current segment
        for( segStart = segment->Next(); ; )
        {
            segStart = segment->GetTrace( segStart, NULL, FLG_START );

            if( segStart )
            {
                // the two segments must have the same width
                if( segment->GetWidth() != segStart->GetWidth() )
                    break;

                // it cannot be a via
                if( segStart->Type() != PCB_TRACE_T )
                    break;

                // We must have only one segment connected
                segStart->SetState( BUSY, true );
                other = segment->GetTrace( m_Brd->m_Track, NULL, FLG_START );
                segStart->SetState( BUSY, false );

                if( other == NULL )
                    flag = 1;           // OK

                break;
            }
            break;
        }

        if( flag )   // We have the starting point of the segment is connected to an other segment
        {
            segDelete = mergeCollinearSegmentIfPossible( segment, segStart, FLG_START );

            if( segDelete )
            {
                no_inc = 1;
                segDelete->DeleteStructure();
                modified = true;
            }
        }

        // search for a possible point connected to the END point of the current segment:
        for( segEnd = segment->Next(); ; )
        {
            segEnd = segment->GetTrace( segEnd, NULL, FLG_END );

            if( segEnd )
            {
                if( segment->GetWidth() != segEnd->GetWidth() )
                    break;

                if( segEnd->Type() != PCB_TRACE_T )
                    break;

                // We must have only one segment connected
                segEnd->SetState( BUSY, true );
                other = segment->GetTrace( m_Brd->m_Track, NULL, FLG_END );
                segEnd->SetState( BUSY, false );

                if( other == NULL )
                    flag |= 2;          // Ok

                break;
            }
            else
            {
                break;
            }
        }

        if( flag & 2 )  // We have the ending point of the segment is connected to an other segment
        {
            segDelete = mergeCollinearSegmentIfPossible( segment, segEnd, FLG_END );

            if( segDelete )
            {
                no_inc = 1;
                segDelete->DeleteStructure();
                modified = true;
            }
        }

        if( no_inc ) // The current segment was modified, retry to merge it
            nextsegment = segment->Next();
    }

    return modified;
}
Ejemplo n.º 16
0
/**
 * Function SwapData
 * Used in undo / redo command:
 *  swap data between Item and a copy
 *  swapped data is data modified by edition, mainly sizes and texts
 * so ONLY FEW values are swapped
 * @param aItem = the item
 * @param aImage = a copy of the item
 */
void SwapData( BOARD_ITEM* aItem, BOARD_ITEM* aImage )
{
    if( aItem == NULL || aImage == NULL )
    {
        wxMessageBox( wxT( "SwapData error: NULL pointer" ) );
        return;
    }

    // Swap layers:
    if( aItem->Type() != PCB_MODULE_T && aItem->Type() != PCB_ZONE_AREA_T )
    {
        // These items have a global swap function.
        int layer, layerimg;
        layer    = aItem->GetLayer();
        layerimg = aImage->GetLayer();
        aItem->SetLayer( layerimg );
        aImage->SetLayer( layer );
    }

    switch( aItem->Type() )
    {
    case PCB_MODULE_T:
        {
            MODULE* tmp = (MODULE*) aImage->Clone();
            ( (MODULE*) aImage )->Copy( (MODULE*) aItem );
            ( (MODULE*) aItem )->Copy( tmp );
            delete tmp;
        }
        break;

    case PCB_ZONE_AREA_T:
        {
            ZONE_CONTAINER* tmp = (ZONE_CONTAINER*) aImage->Clone();
            ( (ZONE_CONTAINER*) aImage )->Copy( (ZONE_CONTAINER*) aItem );
            ( (ZONE_CONTAINER*) aItem )->Copy( tmp );
            delete tmp;
        }
        break;

    case PCB_LINE_T:
#if 0
        EXCHG( ( (DRAWSEGMENT*) aItem )->m_Start, ( (DRAWSEGMENT*) aImage )->m_Start );
        EXCHG( ( (DRAWSEGMENT*) aItem )->m_End, ( (DRAWSEGMENT*) aImage )->m_End );
        EXCHG( ( (DRAWSEGMENT*) aItem )->m_Width, ( (DRAWSEGMENT*) aImage )->m_Width );
        EXCHG( ( (DRAWSEGMENT*) aItem )->m_Shape, ( (DRAWSEGMENT*) aImage )->m_Shape );
#else
        {
            DRAWSEGMENT tmp = *(DRAWSEGMENT*) aImage;
            *aImage = *aItem;
            *aItem  = tmp;
        }
#endif
        break;

    case PCB_TRACE_T:
    case PCB_VIA_T:
        {
            TRACK* track = (TRACK*) aItem;
            TRACK* image = (TRACK*) aImage;

            // swap start, end, width and shape for track and image.
            wxPoint exchp = track->GetStart(); track->SetStart( image->GetStart() ); image->SetStart( exchp );
            exchp = track->GetEnd(); track->SetEnd( image->GetEnd() ); image->SetEnd( exchp );
            int atmp = track->GetWidth(); track->SetWidth( image->GetWidth() ); image->SetWidth( atmp );
            atmp = track->GetShape(); track->SetShape( image->GetShape() ); image->SetShape( atmp );

            atmp = track->GetDrillValue();

            if( track->IsDrillDefault() )
                atmp = -1;

            int itmp = image->GetDrillValue();

            if( image->IsDrillDefault() )
                itmp = -1;

            EXCHG(itmp, atmp );

            if( atmp > 0 )
                track->SetDrill( atmp );
            else
                track->SetDrillDefault();

            if( itmp > 0 )
                image->SetDrill( itmp );
            else
                image->SetDrillDefault();
        }
        break;

    case PCB_TEXT_T:
        EXCHG( ( (TEXTE_PCB*) aItem )->m_Mirror, ( (TEXTE_PCB*) aImage )->m_Mirror );
        EXCHG( ( (TEXTE_PCB*) aItem )->m_Size, ( (TEXTE_PCB*) aImage )->m_Size );
        EXCHG( ( (TEXTE_PCB*) aItem )->m_Pos, ( (TEXTE_PCB*) aImage )->m_Pos );
        EXCHG( ( (TEXTE_PCB*) aItem )->m_Thickness, ( (TEXTE_PCB*) aImage )->m_Thickness );
        EXCHG( ( (TEXTE_PCB*) aItem )->m_Orient, ( (TEXTE_PCB*) aImage )->m_Orient );
        EXCHG( ( (TEXTE_PCB*) aItem )->m_Text, ( (TEXTE_PCB*) aImage )->m_Text );
        EXCHG( ( (TEXTE_PCB*) aItem )->m_Italic, ( (TEXTE_PCB*) aImage )->m_Italic );
        EXCHG( ( (TEXTE_PCB*) aItem )->m_Bold, ( (TEXTE_PCB*) aImage )->m_Bold );
        EXCHG( ( (TEXTE_PCB*) aItem )->m_HJustify, ( (TEXTE_PCB*) aImage )->m_HJustify );
        EXCHG( ( (TEXTE_PCB*) aItem )->m_VJustify, ( (TEXTE_PCB*) aImage )->m_VJustify );
        break;

    case PCB_TARGET_T:
        ( (PCB_TARGET*) aItem )->Exchg( (PCB_TARGET*) aImage );
        break;

    case PCB_DIMENSION_T:
        {
            wxString txt = ( (DIMENSION*) aItem )->GetText();
            ( (DIMENSION*) aItem )->SetText( ( (DIMENSION*) aImage )->GetText() );
            ( (DIMENSION*) aImage )->SetText( txt );
            EXCHG( ( (DIMENSION*) aItem )->m_Width, ( (DIMENSION*) aImage )->m_Width );
            EXCHG( ( (DIMENSION*) aItem )->m_Text.m_Size, ( (DIMENSION*) aImage )->m_Text.m_Size );
            EXCHG( ( (DIMENSION*) aItem )->m_Text.m_Pos, ( (DIMENSION*) aImage )->m_Text.m_Pos );
            EXCHG( ( (DIMENSION*) aItem )->m_Text.m_Thickness,
                   ( (DIMENSION*) aImage )->m_Text.m_Thickness );
            EXCHG( ( (DIMENSION*) aItem )->m_Text.m_Mirror,
                   ( (DIMENSION*) aImage )->m_Text.m_Mirror );
        }
        break;

    case PCB_ZONE_T:
    default:
        wxMessageBox( wxT( "SwapData() error: unexpected type" ) );
        break;
    }
}
MARKER_PCB* DRC::fillMarker( const TRACK* aTrack, BOARD_ITEM* aItem, int aErrorCode,
                             MARKER_PCB* fillMe )
{
    wxString textA = aTrack->GetSelectMenuText();
    wxString textB;

    wxPoint  position;
    wxPoint  posB;

    if( aItem )     // aItem might be NULL
    {
        textB = aItem->GetSelectMenuText();

        if( aItem->Type() == PCB_PAD_T )
        {
            posB = position = ((D_PAD*)aItem)->GetPosition();
        }
        else if( aItem->Type() == PCB_VIA_T )
        {
            posB = position = ((VIA*)aItem)->GetPosition();
        }
        else if( aItem->Type() == PCB_TRACE_T )
        {
            TRACK*  track  = (TRACK*) aItem;

            posB = track->GetPosition();

            wxPoint endPos = track->GetEnd();

            // either of aItem's start or end will be used for the marker position
            // first assume start, then switch at end if needed.  decision made on
            // distance from end of aTrack.
            position = track->GetStart();

            double dToEnd = GetLineLength( endPos, aTrack->GetEnd() );
            double dToStart = GetLineLength( position, aTrack->GetEnd() );

            if( dToEnd < dToStart )
                position = endPos;
        }
    }
    else
        position = aTrack->GetPosition();

    if( fillMe )
    {
        if( aItem )
            fillMe->SetData( aErrorCode, position,
                             textA, aTrack->GetPosition(),
                             textB, posB );
        else
            fillMe->SetData( aErrorCode, position,
                             textA, aTrack->GetPosition() );
    }
    else
    {
        if( aItem )
            fillMe = new MARKER_PCB( aErrorCode, position,
                                     textA, aTrack->GetPosition(),
                                     textB, posB );
        else
            fillMe = new MARKER_PCB( aErrorCode, position,
                                     textA, aTrack->GetPosition() );
    }

    return fillMe;
}
bool DIALOG_TRACK_VIA_PROPERTIES::Apply()
{
    if( !check() )
        return false;

    for( int i = 0; i < m_items.Size(); ++i )
    {
        BOARD_ITEM* item = m_items.Item<BOARD_ITEM>( i );

        switch( item->Type() )
        {
            case PCB_TRACE_T:
            {
                assert( m_tracks );
                TRACK* t = static_cast<TRACK*>( item );

                if( m_trackStartX.Valid() || m_trackStartY.Valid() )
                {
                    wxPoint start = t->GetStart();

                    if( m_trackStartX.Valid() )
                        start.x = m_trackStartX.GetValue();

                    if( m_trackStartY.Valid() )
                        start.y = m_trackStartY.GetValue();

                    t->SetStart( start );
                }

                if( m_trackEndX.Valid() || m_trackEndY.Valid() )
                {
                    wxPoint end = t->GetEnd();

                    if( m_trackEndX.Valid() )
                        end.x = m_trackEndX.GetValue();

                    if( m_trackEndY.Valid() )
                        end.y = m_trackEndY.GetValue();

                    t->SetEnd( end );
                }

                if( m_trackNetclass->IsChecked() )
                {
                    t->SetWidth( t->GetNetClass()->GetTrackWidth() );
                }
                else if( m_trackWidth.Valid() )
                {
                    t->SetWidth( m_trackWidth.GetValue() );
                }

                LAYER_NUM layer = m_TrackLayerCtrl->GetLayerSelection();

                if( layer != UNDEFINED_LAYER )
                    t->SetLayer( (LAYER_ID) layer );

                break;
            }

            case PCB_VIA_T:
            {
                assert( m_vias );

                VIA* v = static_cast<VIA*>( item );

                if( m_viaX.Valid() || m_viaY.Valid() )
                {
                    wxPoint pos = v->GetPosition();

                    if( m_viaX.Valid() )
                        pos.x = m_viaX.GetValue();

                    if( m_viaY.Valid() )
                        pos.y = m_viaY.GetValue();

                    v->SetPosition( pos );
                }

                if( m_viaNetclass->IsChecked() )
                {
                    v->SetWidth( v->GetNetClass()->GetViaDiameter() );
                    v->SetDrill( v->GetNetClass()->GetViaDrill() );
                }
                else
                {
                    if( m_viaDiameter.Valid() )
                        v->SetWidth( m_viaDiameter.GetValue() );

                    if( m_viaDrill.Valid() )
                        v->SetDrill( m_viaDrill.GetValue() );
                }

                break;
            }

            default:
                assert( false );
                break;
        }
    }

    return true;
}
/* drawing the track segment movement
 *  > s_MovingSegmentSlope slope = moving track segment slope
 *  > s_StartSegmentSlope slope = slope of the segment connected to the start
 * point of the moving segment
 *  > s_EndSegmentSlope slope = slope of the segment connected to the end point
 * of the moving segment
 *
 *  moved segment function :
 *      yt=s_MovingSegmentSlope * x + s_MovingSegment_Yorg
 *
 *  segment connected to moved segment's start:
 *      y1 = s_StartSegmentSlope * x + s_StartSegment_Yorg
 *
 *  segment connected to moved segment's end:
 *      y2=s_EndSegmentSlope * x + s_EndSegment_Yorg
 *
 *  first intersection point will be located at
 *      y1=yt ->
 *
 * xi1=(s_MovingSegment_Yorg-s_StartSegment_Yorg)/(s_StartSegmentSlope-s_MovingSegmentSlope)
 *      yi1=s_MovingSegmentSlope*xi1+s_MovingSegment_Yorg
 *      or yi1=s_StartSegmentSlope*xi1+s_MovingSegment_Yorg
 *
 *  second intersection point
 *      y2=yt ->
 *
 * xi2=(s_MovingSegment_Yorg-s_StartSegment_Yorg)/(s_MovingSegmentSlope-s_MovingSegmentSlope)
 *      yi2=s_MovingSegmentSlope*xi2+s_MovingSegment_Yorg
 *      or yi1=s_EndSegmentSlope*xi2+s_MovingSegment_Yorg
 *  !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
 *  !!!!!    special attention to vertical segments because
 *  !!!!!    their slope=infinite
 *  !!!!!    intersection point will be calculated using the
 *  !!!!!    segment intersecting it
 *  !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
 *
 *  Slope parameters are computed once, because they can become undetermined
 * when moving segments
 *  (i.e. when a segment length is 0) and we want keep them constant
 */
static void Show_Drag_Track_Segment_With_Cte_Slope( EDA_DRAW_PANEL* aPanel, wxDC* aDC,
                                                    const wxPoint& aPosition, bool aErase )
{
    double       xi1 = 0, yi1 = 0, xi2 = 0, yi2 = 0;    // calculated intersection points
    double       tx1, tx2, ty1, ty2;                    // temporary storage of points
    int          dx, dy;
    bool         update = true;
    TRACK*       Track;
    TRACK*       tSegmentToStart = NULL, * tSegmentToEnd = NULL;

    if( g_DragSegmentList.size() == 0 )
        return;

    /* get the segments :
     * from last to first in list are:
     * the segment to move
     * the segment connected to its end point (if exists)
     * the segment connected to its start point (if exists)
     */
    int ii = g_DragSegmentList.size() - 1;
    Track = g_DragSegmentList[ii].m_Track;

    if( Track == NULL )
        return;

    ii--;

    if( ii >= 0)
    {
        if( s_EndSegmentPresent )
        {
            // Get the segment connected to the end point
            tSegmentToEnd   = g_DragSegmentList[ii].m_Track;
            ii--;
        }

        if( s_StartSegmentPresent )
        {
            // Get the segment connected to the start point
            if( ii >= 0 )
                tSegmentToStart = g_DragSegmentList[ii].m_Track;
        }
    }

    GR_DRAWMODE draw_mode = GR_XOR | GR_HIGHLIGHT;

    // Undraw the current moved track segments before modification

#ifndef USE_WX_OVERLAY
//  if( erase )
    {
        Track->Draw( aPanel, aDC, draw_mode );

        if( tSegmentToStart )
            tSegmentToStart->Draw( aPanel, aDC, draw_mode );

        if( tSegmentToEnd )
            tSegmentToEnd->Draw( aPanel, aDC, draw_mode );
    }
#endif

    // Compute the new track segment position
    wxPoint Pos = aPanel->GetParent()->GetCrossHairPosition();

    dx = Pos.x - s_LastPos.x;
    dy = Pos.y - s_LastPos.y;

    // move the line by dx and dy
    tx1 = (double) ( Track->GetStart().x + dx );
    ty1 = (double) ( Track->GetStart().y + dy );
    tx2 = (double) ( Track->GetEnd().x + dx );
    ty2 = (double) ( Track->GetEnd().y + dy );

    // recalculate the segments new parameters and intersection points
    // only the intercept will change, segment slopes does not change
    // because we are moving parallel with is initial state
    if( !s_MovingSegmentVertical )
    {
        s_MovingSegment_Yorg = ty1 - ( s_MovingSegmentSlope * tx1 );
    }

    if( ( !s_EndPointVertical ) && ( !s_MovingSegmentVertical ) )
    {
        xi2 = ( s_MovingSegment_Yorg - s_EndSegment_Yorg )
            / ( s_EndSegmentSlope - s_MovingSegmentSlope );
    }
    else
    {
        if( !s_EndPointVertical )
        {
            xi2 = tx2;
        }
        else
        {
            //P1=P2
            if( !s_EndPointHorizontal )
            {
                xi2 = tx2 - dx;
            }
            else
            {
                update = false;
            }
        }
    }

    if( !s_MovingSegmentVertical )
    {
        yi2 = s_MovingSegmentSlope * ( xi2 ) + s_MovingSegment_Yorg;
    }
    else
    {
        if( !s_EndPointVertical )
        {
            yi2 = s_EndSegmentSlope * ( xi2 ) + s_EndSegment_Yorg;
        }
        else
        {
            if( !s_EndPointHorizontal )
            {
                update = false;
            }
            else
            {
                yi2 = s_MovingSegmentSlope * ( xi2 ) + s_MovingSegment_Yorg;
            }
        }
    }

    if( ( !s_StartPointVertical ) && ( !s_MovingSegmentVertical ) )
    {
        xi1 = ( s_MovingSegment_Yorg - s_StartSegment_Yorg )
            / ( s_StartSegmentSlope - s_MovingSegmentSlope );
    }
    else
    {
        if( !s_StartPointVertical )
        {
            xi1 = tx1;
        }
        else
        {
            //P1=P2
            if( !s_StartPointHorizontal )
            {
                xi1 = tx1 - dx;
            }
            else
            {
                if( !s_StartPointHorizontal )
                {
                    update = false;
                }
            }
        }
    }

    if( !s_MovingSegmentVertical )
    {
        yi1 = s_MovingSegmentSlope * ( xi1 ) + s_MovingSegment_Yorg;
    }
    else
    {
        if( !s_StartPointVertical )
        {
            yi1 = s_StartSegmentSlope * ( xi1 ) + s_StartSegment_Yorg;
        }
        else
        {
            if( !s_StartPointHorizontal )
            {
                update = false;
            }
            else
            {
                yi2 = s_MovingSegmentSlope * ( xi1 ) + s_MovingSegment_Yorg;
            }
        }
    }

    // update the segment coordinates (if possible)
    if( tSegmentToStart == NULL )
    {
        xi1 = tx1;
        yi1 = ty1;
    }

    if( tSegmentToEnd == NULL )
    {
        xi2 = tx2;
        yi2 = ty2;
    }

    if( update )
    {
        s_LastPos = Pos;
        Track->SetStart( wxPoint( KiROUND( xi1 ), KiROUND( yi1 ) ) );
        Track->SetEnd( wxPoint( KiROUND( xi2 ), KiROUND( yi2 ) ) );

        if( tSegmentToEnd )
        {
            if( tSegmentToEnd->GetFlags() & STARTPOINT )
                tSegmentToEnd->SetStart( Track->GetEnd() );
            else
                tSegmentToEnd->SetEnd( Track->GetEnd() );
        }

        if( tSegmentToStart )
        {
            if( tSegmentToStart->GetFlags() & STARTPOINT )
                tSegmentToStart->SetStart( Track->GetStart() );
            else
                tSegmentToStart->SetEnd( Track->GetStart() );
        }
    }

    Track->Draw( aPanel, aDC, draw_mode );

    if( tSegmentToStart )
        tSegmentToStart->Draw( aPanel, aDC, draw_mode );

    if( tSegmentToEnd )
        tSegmentToEnd->Draw( aPanel, aDC, draw_mode );

    // Display track length
    PCB_BASE_FRAME* frame = (PCB_BASE_FRAME*) aPanel->GetParent();
    frame->SetMsgPanel( Track );
}
Ejemplo n.º 20
0
void BOARD_ITEM::SwapData( BOARD_ITEM* aImage )
{
    if( aImage == NULL )
        return;

    // Remark: to create images of edited items to undo, we are using Clone method
    // which can duplication of items foe copy, but does not clone all members
    // mainly pointers in chain and time stamp, which is set to new, unique value.
    // So we have to use the current values of these parameters.

    EDA_ITEM * pnext = Next();
    EDA_ITEM * pback = Back();
    DHEAD* mylist    = m_List;
    time_t timestamp = GetTimeStamp();

    switch( Type() )
    {
    case PCB_MODULE_T:
    {
        MODULE* tmp = (MODULE*) aImage->Clone();
        ( (MODULE*) aImage )->Copy( (MODULE*) this );
        ( (MODULE*) this )->Copy( tmp );
        delete tmp;
    }
        break;

    case PCB_ZONE_AREA_T:
    {
        ZONE_CONTAINER* tmp = (ZONE_CONTAINER*) aImage->Clone();
        ( (ZONE_CONTAINER*) aImage )->Copy( (ZONE_CONTAINER*) this );
        ( (ZONE_CONTAINER*) this )->Copy( tmp );
        delete tmp;
    }
        break;

    case PCB_LINE_T:
        std::swap( *((DRAWSEGMENT*)this), *((DRAWSEGMENT*)aImage) );
        break;

    case PCB_TRACE_T:
    case PCB_VIA_T:
    {
        TRACK* track = (TRACK*) this;
        TRACK* image = (TRACK*) aImage;

        std::swap(track->m_Layer, image->m_Layer );

        // swap start, end, width and shape for track and image.
        wxPoint exchp = track->GetStart();
        track->SetStart( image->GetStart() );
        image->SetStart( exchp );
        exchp = track->GetEnd();
        track->SetEnd( image->GetEnd() );
        image->SetEnd( exchp );

        int atmp = track->GetWidth();
        track->SetWidth( image->GetWidth() );
        image->SetWidth( atmp );

        if( Type() == PCB_VIA_T )
        {
            VIA *via = static_cast<VIA*>( this );
            VIA *viaimage = static_cast<VIA*>( aImage );

            VIATYPE_T viatmp = via->GetViaType();
            via->SetViaType( viaimage->GetViaType() );
            viaimage->SetViaType( viatmp );

            int drilltmp = via->GetDrillValue();

            if( via->IsDrillDefault() )
                drilltmp = -1;

            int itmp = viaimage->GetDrillValue();

            if( viaimage->IsDrillDefault() )
                itmp = -1;

            std::swap(itmp, drilltmp );

            if( drilltmp > 0 )
                via->SetDrill( drilltmp );
            else
                via->SetDrillDefault();

            if( itmp > 0 )
                viaimage->SetDrill( itmp );
            else
                viaimage->SetDrillDefault();
        }
    }
        break;

    case PCB_TEXT_T:
        std::swap( *((TEXTE_PCB*)this), *((TEXTE_PCB*)aImage) );
        break;

    case PCB_TARGET_T:
        std::swap( *((PCB_TARGET*)this), *((PCB_TARGET*)aImage) );
        break;

    case PCB_DIMENSION_T:
        std::swap( *((DIMENSION*)this), *((DIMENSION*)aImage) );
        break;

    case PCB_ZONE_T:
    default:
        wxLogMessage( wxT( "SwapData() error: unexpected type %d" ), Type() );
        break;
    }

    // Restore pointers and time stamp, to be sure they are not broken
    Pnext = pnext;
    Pback = pback;
    m_List = mylist;
    SetTimeStamp( timestamp );
}
/* Plot a copper layer or mask.
 * Silk screen layers are not plotted here.
 */
void PlotStandardLayer( BOARD *aBoard, PLOTTER* aPlotter,
                        LAYER_MSK aLayerMask, const PCB_PLOT_PARAMS& aPlotOpt )
{

    BRDITEMS_PLOTTER itemplotter( aPlotter, aBoard, aPlotOpt );
    itemplotter.SetLayerMask( aLayerMask );

    EDA_DRAW_MODE_T plotMode = aPlotOpt.GetMode();

     // Plot edge layer and graphic items
    itemplotter.PlotBoardGraphicItems();

    // Draw footprint shapes without pads (pads will plotted later)
    // We plot here module texts, but they are usually on silkscreen layer,
    // so they are not plot here but plot by PlotSilkScreen()
    // Plot footprints fields (ref, value ...)
    for( MODULE* module = aBoard->m_Modules;  module;  module = module->Next() )
    {
        if( ! itemplotter.PlotAllTextsModule( module ) )
        {
            wxLogMessage( _( "Your BOARD has a bad layer number for module %s" ),
                           GetChars( module->GetReference() ) );
        }
    }

    for( MODULE* module = aBoard->m_Modules;  module;  module = module->Next() )
    {
        for( BOARD_ITEM* item = module->GraphicalItems(); item; item = item->Next() )
        {
            if( ! (aLayerMask & GetLayerMask( item->GetLayer() ) ) )
                continue;

            switch( item->Type() )
            {
            case PCB_MODULE_EDGE_T:
                itemplotter.Plot_1_EdgeModule( (EDGE_MODULE*) item );
                break;

            default:
                break;
            }
        }
    }

    // Plot footprint pads
    for( MODULE* module = aBoard->m_Modules;  module;  module = module->Next() )
    {
        for( D_PAD* pad = module->Pads();  pad;  pad = pad->Next() )
        {
            if( (pad->GetLayerMask() & aLayerMask) == 0 )
                continue;

            wxSize margin;
            double width_adj = 0;

            if( aLayerMask & ALL_CU_LAYERS )
                width_adj =  itemplotter.getFineWidthAdj();

            switch( aLayerMask &
                   ( SOLDERMASK_LAYER_BACK | SOLDERMASK_LAYER_FRONT |
                     SOLDERPASTE_LAYER_BACK | SOLDERPASTE_LAYER_FRONT ) )
            {
            case SOLDERMASK_LAYER_FRONT:
            case SOLDERMASK_LAYER_BACK:
                margin.x = margin.y = pad->GetSolderMaskMargin();
                break;

            case SOLDERPASTE_LAYER_FRONT:
            case SOLDERPASTE_LAYER_BACK:
                margin = pad->GetSolderPasteMargin();
                break;

            default:
                break;
            }

            wxSize padPlotsSize;
            padPlotsSize.x = pad->GetSize().x + ( 2 * margin.x ) + width_adj;
            padPlotsSize.y = pad->GetSize().y + ( 2 * margin.y ) + width_adj;

            // Don't draw a null size item :
            if( padPlotsSize.x <= 0 || padPlotsSize.y <= 0 )
                continue;

            EDA_COLOR_T color = BLACK;

            if( (pad->GetLayerMask() & LAYER_BACK) )
               color = aBoard->GetVisibleElementColor( PAD_BK_VISIBLE );

            if((pad->GetLayerMask() & LAYER_FRONT ) )
                color = ColorFromInt( color | aBoard->GetVisibleElementColor( PAD_FR_VISIBLE ) );

            // Temporary set the pad size to the required plot size:
            wxSize tmppadsize = pad->GetSize();
            pad->SetSize( padPlotsSize );
            switch( pad->GetShape() )
            {
            case PAD_CIRCLE:
            case PAD_OVAL:
                if( aPlotOpt.GetSkipPlotNPTH_Pads() &&
                    (pad->GetSize() == pad->GetDrillSize()) &&
                    (pad->GetAttribute() == PAD_HOLE_NOT_PLATED) )
                    break;

                // Fall through:
            case PAD_TRAPEZOID:
            case PAD_RECT:
            default:
                itemplotter.PlotPad( pad, color, plotMode );
                break;
            }

            pad->SetSize( tmppadsize );     // Restore the pad size
        }
    }

    // Plot vias on copper layers, and if aPlotOpt.GetPlotViaOnMaskLayer() is true,
    // plot them on solder mask
    for( TRACK* track = aBoard->m_Track; track; track = track->Next() )
    {
        const VIA* Via = dynamic_cast<const VIA*>( track );

        if( !Via )
            continue;

        // vias are not plotted if not on selected layer, but if layer
        // is SOLDERMASK_LAYER_BACK or SOLDERMASK_LAYER_FRONT,vias are drawn,
        // only if they are on the corresponding external copper layer
        int via_mask_layer = Via->GetLayerMask();

        if( aPlotOpt.GetPlotViaOnMaskLayer() )
        {
            if( via_mask_layer & LAYER_BACK )
                via_mask_layer |= SOLDERMASK_LAYER_BACK;

            if( via_mask_layer & LAYER_FRONT )
                via_mask_layer |= SOLDERMASK_LAYER_FRONT;
        }

        if( ( via_mask_layer & aLayerMask ) == 0 )
            continue;

        int via_margin = 0;
        double width_adj = 0;

        // If the current layer is a solder mask, use the global mask
        // clearance for vias
        if( ( aLayerMask & ( SOLDERMASK_LAYER_BACK | SOLDERMASK_LAYER_FRONT ) ) )
            via_margin = aBoard->GetDesignSettings().m_SolderMaskMargin;

        if( aLayerMask & ALL_CU_LAYERS )
            width_adj = itemplotter.getFineWidthAdj();

        int diameter = Via->GetWidth() + 2 * via_margin + width_adj;

        // Don't draw a null size item :
        if( diameter <= 0 )
            continue;

        EDA_COLOR_T color = aBoard->GetVisibleElementColor(VIAS_VISIBLE + Via->GetViaType());
        // Set plot color (change WHITE to LIGHTGRAY because
        // the white items are not seen on a white paper or screen
        aPlotter->SetColor( color != WHITE ? color : LIGHTGRAY);
        aPlotter->FlashPadCircle( Via->GetStart(), diameter, plotMode );
    }

    // Plot tracks (not vias) :
    for( TRACK* track = aBoard->m_Track; track; track = track->Next() )
    {
        if( track->Type() == PCB_VIA_T )
            continue;

        if( (GetLayerMask( track->GetLayer() ) & aLayerMask) == 0 )
            continue;

        int width = track->GetWidth() + itemplotter.getFineWidthAdj();
        aPlotter->SetColor( itemplotter.getColor( track->GetLayer() ) );
        aPlotter->ThickSegment( track->GetStart(), track->GetEnd(), width, plotMode );
    }

    // Plot zones (outdated, for old boards compatibility):
    for( TRACK* track = aBoard->m_Zone; track; track = track->Next() )
    {
        if( (GetLayerMask( track->GetLayer() ) & aLayerMask) == 0 )
            continue;

        int width = track->GetWidth() + itemplotter.getFineWidthAdj();
        aPlotter->SetColor( itemplotter.getColor( track->GetLayer() ) );
        aPlotter->ThickSegment( track->GetStart(), track->GetEnd(), width, plotMode );
    }

    // Plot filled ares
    for( int ii = 0; ii < aBoard->GetAreaCount(); ii++ )
    {
        ZONE_CONTAINER* zone = aBoard->GetArea( ii );

        if( ( GetLayerMask(zone->GetLayer() )  & aLayerMask ) == 0 )
            continue;

        itemplotter.PlotFilledAreas( zone );
    }

    // Adding drill marks, if required and if the plotter is able to plot them:
    if( aPlotOpt.GetDrillMarksType() != PCB_PLOT_PARAMS::NO_DRILL_SHAPE )
        itemplotter.PlotDrillMarks();
}
void ZONE_CONTAINER::TestForCopperIslandAndRemoveInsulatedIslands( BOARD* aPcb )
{
    if( m_FilledPolysList.GetCornersCount() == 0 )
        return;

    // Build a list of points connected to the net:
    // list of coordinates of pads and vias on this layer and on this net.
    std::vector <wxPoint> listPointsCandidates;

    for( MODULE* module = aPcb->m_Modules; module; module = module->Next() )
    {
        for( D_PAD* pad = module->Pads(); pad != NULL; pad = pad->Next() )
        {
            if( !pad->IsOnLayer( GetLayer() ) )
                continue;

            if( pad->GetNet() != GetNet() )
                continue;

            listPointsCandidates.push_back( pad->GetPosition() );
        }
    }

    for( TRACK* track = aPcb->m_Track; track; track = track->Next() )
    {
        if( !track->IsOnLayer( GetLayer() ) )
            continue;

        if( track->GetNet() != GetNet() )
            continue;

        listPointsCandidates.push_back( track->GetStart() );

        if( track->Type() != PCB_VIA_T )
            listPointsCandidates.push_back( track->GetEnd() );
    }

    // test if a point is inside
    unsigned indexstart = 0, indexend;
    bool     connected  = false;

    for( indexend = 0; indexend < m_FilledPolysList.GetCornersCount(); indexend++ )
    {
        if( m_FilledPolysList[indexend].end_contour )    // end of a filled sub-area found
        {
            EDA_RECT bbox = CalculateSubAreaBoundaryBox( indexstart, indexend );

            for( unsigned ic = 0; ic < listPointsCandidates.size(); ic++ )
            {
                // test if this area is connected to a board item:
                wxPoint pos = listPointsCandidates[ic];

                if( !bbox.Contains( pos ) )
                    continue;

                if( TestPointInsidePolygon( m_FilledPolysList, indexstart, indexend,
                                            pos.x, pos.y ) )
                {
                    connected = true;
                    break;
                }
            }

            if( connected )                 // this polygon is connected: analyse next polygon
            {
                indexstart = indexend + 1;  // indexstart points the first point of the next polygon
                connected  = false;
            }
            else                             // Not connected: remove this polygon
            {
                m_FilledPolysList.DeleteCorners( indexstart, indexend );
                indexend = indexstart;   /* indexstart points the first point of the next polygon
                                          * because the current poly is removed */
            }
        }
    }
}
Ejemplo n.º 23
0
bool TRACKS_CLEANER::clean_vias()
{
    TRACK* next_track;
    bool modified = false;

    for( TRACK* track = m_Brd->m_Track; track; track = track->Next() )
    {
        // Correct via m_End defects (if any)
        if( track->Type() == PCB_VIA_T )
        {
            if( track->GetStart() != track->GetEnd() )
                track->SetEnd( track->GetStart() );
        }

        if( track->GetShape() != VIA_THROUGH )
            continue;

        // Search and delete others vias at same location
        TRACK* alt_track = track->Next();

        for( ; alt_track != NULL; alt_track = next_track )
        {
            next_track = alt_track->Next();

            if( alt_track->GetShape() != VIA_THROUGH )
                continue;

            if( alt_track->GetStart() != track->GetStart() )
                continue;

            // delete via
            alt_track->UnLink();
            delete alt_track;
            modified = true;
        }
    }

    // Delete Via on pads at same location
    for( TRACK* track = m_Brd->m_Track; track != NULL; track = next_track )
    {
        next_track = track->Next();

        if( track->GetShape() != VIA_THROUGH )
            continue;

        // Examine the list of connected pads:
        // if one pad through is found, the via can be removed
        for( unsigned ii = 0; ii < track->m_PadsConnected.size(); ii++ )
        {
            D_PAD * pad = track->m_PadsConnected[ii];

            if( (pad->GetLayerMask() & ALL_CU_LAYERS) == ALL_CU_LAYERS )
            {
                // redundant: via delete it
                track->UnLink();
                delete track;
                modified = true;
                break;
            }
        }
    }

    return modified;
}
Ejemplo n.º 24
0
/* This function is used by Retrace and read the autorouting matrix data cells to create
 * the real track on the physical board
 */
static void OrCell_Trace( BOARD* pcb, int col, int row,
                          int side, int orient, int current_net_code )
{
    if( orient == HOLE )  // placement of a via
    {
        VIA *newVia = new VIA( pcb );

        g_CurrentTrackList.PushBack( newVia );

        g_CurrentTrackSegment->SetState( TRACK_AR, true );
        g_CurrentTrackSegment->SetLayer( F_Cu );

        g_CurrentTrackSegment->SetStart(wxPoint( pcb->GetBoundingBox().GetX() +
                                                ( RoutingMatrix.m_GridRouting * row ),
                                                pcb->GetBoundingBox().GetY() +
                                                ( RoutingMatrix.m_GridRouting * col )));
        g_CurrentTrackSegment->SetEnd( g_CurrentTrackSegment->GetStart() );

        g_CurrentTrackSegment->SetWidth( pcb->GetDesignSettings().GetCurrentViaSize() );
        newVia->SetViaType( pcb->GetDesignSettings().m_CurrentViaType );

        g_CurrentTrackSegment->SetNetCode( current_net_code );
    }
    else    // placement of a standard segment
    {
        TRACK *newTrack = new TRACK( pcb );
        int    dx0, dy0, dx1, dy1;


        g_CurrentTrackList.PushBack( newTrack );

        g_CurrentTrackSegment->SetLayer( g_Route_Layer_BOTTOM );

        if( side == TOP )
            g_CurrentTrackSegment->SetLayer( g_Route_Layer_TOP );

        g_CurrentTrackSegment->SetState( TRACK_AR, true );
        g_CurrentTrackSegment->SetEnd( wxPoint( pcb->GetBoundingBox().GetX() +
                                         ( RoutingMatrix.m_GridRouting * row ),
                                         pcb->GetBoundingBox().GetY() +
                                         ( RoutingMatrix.m_GridRouting * col )));
        g_CurrentTrackSegment->SetNetCode( current_net_code );

        if( g_CurrentTrackSegment->Back() == NULL ) // Start trace.
        {
            g_CurrentTrackSegment->SetStart( wxPoint( segm_fX, segm_fY ) );

            // Placement on the center of the pad if outside grid.
            dx1 = g_CurrentTrackSegment->GetEnd().x - g_CurrentTrackSegment->GetStart().x;
            dy1 = g_CurrentTrackSegment->GetEnd().y - g_CurrentTrackSegment->GetStart().y;

            dx0 = pt_cur_ch->m_PadEnd->GetPosition().x - g_CurrentTrackSegment->GetStart().x;
            dy0 = pt_cur_ch->m_PadEnd->GetPosition().y - g_CurrentTrackSegment->GetStart().y;

            // If aligned, change the origin point.
            if( abs( dx0 * dy1 ) == abs( dx1 * dy0 ) )
            {
                g_CurrentTrackSegment->SetStart( pt_cur_ch->m_PadEnd->GetPosition() );
            }
            else    // Creation of a supplemental segment
            {
                g_CurrentTrackSegment->SetStart( pt_cur_ch->m_PadEnd->GetPosition() );

                newTrack = (TRACK*)g_CurrentTrackSegment->Clone();
                newTrack->SetStart( g_CurrentTrackSegment->GetEnd());

                g_CurrentTrackList.PushBack( newTrack );
            }
        }
        else
        {
            if( g_CurrentTrackSegment->Back() )
            {
                g_CurrentTrackSegment->SetStart( g_CurrentTrackSegment->Back()->GetEnd() );
            }
        }

        g_CurrentTrackSegment->SetWidth( pcb->GetDesignSettings().GetCurrentTrackWidth() );

        if( g_CurrentTrackSegment->GetStart() != g_CurrentTrackSegment->GetEnd() )
        {
            // Reduce aligned segments by one.
            TRACK* oldTrack = g_CurrentTrackSegment->Back();

            if( oldTrack &&  oldTrack->Type() != PCB_VIA_T )
            {
                dx1 = g_CurrentTrackSegment->GetEnd().x - g_CurrentTrackSegment->GetStart().x;
                dy1 = g_CurrentTrackSegment->GetEnd().y - g_CurrentTrackSegment->GetStart().y;

                dx0 = oldTrack->GetEnd().x - oldTrack->GetStart().x;
                dy0 = oldTrack->GetEnd().y - oldTrack->GetStart().y;

                if( abs( dx0 * dy1 ) == abs( dx1 * dy0 ) )
                {
                    oldTrack->SetEnd( g_CurrentTrackSegment->GetEnd() );

                    delete g_CurrentTrackList.PopBack();
                }
            }
        }
    }
}
Ejemplo n.º 25
0
/*
 *  Delete dangling tracks
 *  Vias:
 *  If a via is only connected to a dangling track, it also will be removed
 */
bool TRACKS_CLEANER::deleteUnconnectedTracks()
{
    if( m_Brd->m_Track == NULL )
        return false;

    bool modified = false;
    bool item_erased = true;
    while( item_erased )    // Iterate when at least one track is deleted
    {
        item_erased = false;
        TRACK* next_track;
        for( TRACK * track = m_Brd->m_Track; track ; track = next_track )
        {
            next_track = track->Next();

            int flag_erase = 0; //Not connected indicator
            int type_end = 0;

            if( track->GetState( START_ON_PAD ) )
                type_end |= START_ON_PAD;

            if( track->GetState( END_ON_PAD ) )
                type_end |= END_ON_PAD;

            // if the track start point is not connected to a pad,
            // test if this track start point is connected to another track
            // For via test, an enhancement could be to test if connected
            // to 2 items on different layers.
            // Currently a via must be connected to 2 items, that can be on the same layer
            LAYER_NUM top_layer, bottom_layer;
            ZONE_CONTAINER* zone;

            if( (type_end & START_ON_PAD ) == 0 )
            {
                TRACK* other = track->GetTrace( m_Brd->m_Track, NULL, FLG_START );

                if( other == NULL )     // Test a connection to zones
                {
                    if( track->Type() != PCB_VIA_T )
                    {
                        zone = m_Brd->HitTestForAnyFilledArea( track->GetStart(),
                                                               track->GetLayer(),
                                                               track->GetLayer(),
                                                               track->GetNetCode() );
                    }
                    else
                    {
                        ((SEGVIA*)track)->LayerPair( &top_layer, &bottom_layer );
                        zone = m_Brd->HitTestForAnyFilledArea( track->GetStart(),
                                                               top_layer, bottom_layer,
                                                               track->GetNetCode() );
                    }
                }

                if( (other == NULL) && (zone == NULL) )
                {
                    flag_erase |= 1;
                }
                else    // segment, via or zone connected to this end
                {
                    track->start = other;
                    // If a via is connected to this end,
                    // test if this via has a second item connected.
                    // If no, remove it with the current segment

                    if( other && other->Type() == PCB_VIA_T )
                    {
                        // search for another segment following the via
                        track->SetState( BUSY, true );

                        SEGVIA* via = (SEGVIA*) other;
                        other = via->GetTrace( m_Brd->m_Track, NULL, FLG_START );

                        if( other == NULL )
                        {
                            via->LayerPair( &top_layer, &bottom_layer );
                            zone = m_Brd->HitTestForAnyFilledArea( via->GetStart(),
                                                                   bottom_layer,
                                                                   top_layer,
                                                                   via->GetNetCode() );
                        }

                        if( (other == NULL) && (zone == NULL) )
                            flag_erase |= 2;

                        track->SetState( BUSY, false );
                    }
                }
            }

            // if track end point is not connected to a pad,
            // test if this track end point is connected to an other track
            if( (type_end & END_ON_PAD ) == 0 )
            {
                TRACK* other = track->GetTrace( m_Brd->m_Track, NULL, FLG_END );

                if( other == NULL )     // Test a connection to zones
                {
                    if( track->Type() != PCB_VIA_T )
                    {
                        zone = m_Brd->HitTestForAnyFilledArea( track->GetEnd(),
                                                               track->GetLayer(),
                                                               track->GetLayer(),
                                                               track->GetNetCode() );
                    }
                    else
                    {
                        ((SEGVIA*)track)->LayerPair( &top_layer, &bottom_layer );
                        zone = m_Brd->HitTestForAnyFilledArea( track->GetEnd(),
                                                               top_layer, bottom_layer,
                                                               track->GetNetCode() );
                    }
                }

                if ( (other == NULL) && (zone == NULL) )
                {
                    flag_erase |= 0x10;
                }
                else     // segment, via or zone connected to this end
                {
                    track->end = other;

                    // If a via is connected to this end, test if this via has a second item connected
                    // if no, remove it with the current segment

                    if( other && other->Type() == PCB_VIA_T )
                    {
                        // search for another segment following the via

                        track->SetState( BUSY, true );

                        SEGVIA* via = (SEGVIA*) other;
                        other = via->GetTrace( m_Brd->m_Track, NULL, FLG_END );

                        if( other == NULL )
                        {
                            via->LayerPair( &top_layer, &bottom_layer );
                            zone = m_Brd->HitTestForAnyFilledArea( via->GetEnd(),
                                                                   bottom_layer, top_layer,
                                                                   via->GetNetCode() );
                        }

                        if( (other == NULL) && (zone == NULL) )
                            flag_erase |= 0x20;

                        track->SetState( BUSY, false );
                    }
                }
            }

            if( flag_erase )
            {
                // remove segment from board
                track->DeleteStructure();
                // iterate, because a track connected to the deleted track
                // is now perhaps now not connected and should be deleted
                item_erased = true;
                modified = true;
            }
        }
    }

    return modified;
}
Ejemplo n.º 26
0
bool DIALOG_TRACK_VIA_PROPERTIES::Apply( COMMIT& aCommit )
{
    if( !check() )
        return false;

    bool changeLock = m_lockedCbox->Get3StateValue() != wxCHK_UNDETERMINED;
    bool setLock = m_lockedCbox->Get3StateValue() == wxCHK_CHECKED;

    for( auto item : m_items )
    {
        aCommit.Modify( item );

        switch( item->Type() )
        {
            case PCB_TRACE_T:
            {
                assert( m_tracks );
                TRACK* t = static_cast<TRACK*>( item );

                if( m_trackStartX.Valid() || m_trackStartY.Valid() )
                {
                    wxPoint start = t->GetStart();

                    if( m_trackStartX.Valid() )
                        start.x = m_trackStartX.GetValue();

                    if( m_trackStartY.Valid() )
                        start.y = m_trackStartY.GetValue();

                    t->SetStart( start );
                }

                if( m_trackEndX.Valid() || m_trackEndY.Valid() )
                {
                    wxPoint end = t->GetEnd();

                    if( m_trackEndX.Valid() )
                        end.x = m_trackEndX.GetValue();

                    if( m_trackEndY.Valid() )
                        end.y = m_trackEndY.GetValue();

                    t->SetEnd( end );
                }

                if( m_trackNetclass->IsChecked() )
                {
                    t->SetWidth( t->GetNetClass()->GetTrackWidth() );
                }
                else if( m_trackWidth.Valid() )
                {
                    t->SetWidth( m_trackWidth.GetValue() );
                }

                LAYER_NUM layer = m_TrackLayerCtrl->GetLayerSelection();

                if( layer != UNDEFINED_LAYER )
                    t->SetLayer( (LAYER_ID) layer );

                if( changeLock )
                    t->SetLocked( setLock );

                break;
            }

            case PCB_VIA_T:
            {
                assert( m_vias );

                VIA* v = static_cast<VIA*>( item );

                if( m_viaX.Valid() || m_viaY.Valid() )
                {
                    wxPoint pos = v->GetPosition();

                    if( m_viaX.Valid() )
                        pos.x = m_viaX.GetValue();

                    if( m_viaY.Valid() )
                        pos.y = m_viaY.GetValue();

                    v->SetPosition( pos );
                }

                if( m_viaNetclass->IsChecked() )
                {
                    switch( v->GetViaType() )
                    {
                    default:
                        wxFAIL_MSG("Unhandled via type");
                        // fall through

                    case VIA_THROUGH:
                    case VIA_BLIND_BURIED:
                        v->SetWidth( v->GetNetClass()->GetViaDiameter() );
                        v->SetDrill( v->GetNetClass()->GetViaDrill() );
                        break;

                    case VIA_MICROVIA:
                        v->SetWidth( v->GetNetClass()->GetuViaDiameter() );
                        v->SetDrill( v->GetNetClass()->GetuViaDrill() );
                        break;
                    }
                }
                else
                {
                    if( m_viaDiameter.Valid() )
                        v->SetWidth( m_viaDiameter.GetValue() );

                    if( m_viaDrill.Valid() )
                        v->SetDrill( m_viaDrill.GetValue() );
                }

                if( changeLock )
                    v->SetLocked( setLock );

                break;
            }

            default:
                assert( false );
                break;
        }
    }

    return true;
}
void GRID_HELPER::computeAnchors( BOARD_ITEM* aItem, const VECTOR2I& aRefPos )
{
    VECTOR2I origin;

    switch( aItem->Type() )
    {
        case PCB_MODULE_T:
        {
            MODULE* mod = static_cast<MODULE*>( aItem );
            addAnchor( mod->GetPosition(), ORIGIN | SNAPPABLE, mod );

            for( D_PAD* pad = mod->Pads(); pad; pad = pad->Next() )
                addAnchor( pad->GetPosition(), CORNER | SNAPPABLE, pad );

            break;
        }


        case PCB_PAD_T:
        {
            D_PAD* pad = static_cast<D_PAD*>( aItem );
            addAnchor( pad->GetPosition(), CORNER | SNAPPABLE, pad );

            break;
        }

        case PCB_MODULE_EDGE_T:
        case PCB_LINE_T:
        {
            DRAWSEGMENT* dseg = static_cast<DRAWSEGMENT*>( aItem );
            VECTOR2I start = dseg->GetStart();
            VECTOR2I end = dseg->GetEnd();
            //LAYER_ID layer = dseg->GetLayer();

            switch( dseg->GetShape() )
            {
                case S_CIRCLE:
                {
                    int r = ( start - end ).EuclideanNorm();

                    addAnchor( start, ORIGIN | SNAPPABLE, dseg );
                    addAnchor( start + VECTOR2I( -r, 0 ), OUTLINE | SNAPPABLE, dseg );
                    addAnchor( start + VECTOR2I( r, 0 ), OUTLINE | SNAPPABLE, dseg );
                    addAnchor( start + VECTOR2I( 0, -r ), OUTLINE | SNAPPABLE, dseg );
                    addAnchor( start + VECTOR2I( 0, r ), OUTLINE | SNAPPABLE, dseg );
                    break;
                }

                case S_ARC:
                {
                    origin = dseg->GetCenter();
                    addAnchor( dseg->GetArcStart(), CORNER | SNAPPABLE, dseg );
                    addAnchor( dseg->GetArcEnd(), CORNER | SNAPPABLE, dseg );
                    addAnchor( origin, ORIGIN | SNAPPABLE, dseg );
                    break;
                }

                case S_SEGMENT:
                {
                    origin.x = start.x + ( start.x - end.x ) / 2;
                    origin.y = start.y + ( start.y - end.y ) / 2;
                    addAnchor( start, CORNER | SNAPPABLE, dseg );
                    addAnchor( end, CORNER | SNAPPABLE, dseg );
                    addAnchor( origin, ORIGIN, dseg );
                    break;
                }

                default:
                {
                    origin = dseg->GetStart();
                    addAnchor( origin, ORIGIN | SNAPPABLE, dseg );
                    break;
                }
            }
            break;
        }

        case PCB_TRACE_T:
        {
            TRACK* track = static_cast<TRACK*>( aItem );
            VECTOR2I start = track->GetStart();
            VECTOR2I end = track->GetEnd();
            origin.x = start.x + ( start.x - end.x ) / 2;
            origin.y = start.y + ( start.y - end.y ) / 2;
            addAnchor( start, CORNER | SNAPPABLE, track );
            addAnchor( end, CORNER | SNAPPABLE, track );
            addAnchor( origin, ORIGIN, track);
            break;
        }

        case PCB_VIA_T:
            addAnchor( aItem->GetPosition(), CORNER | SNAPPABLE, aItem );
            break;

        case PCB_ZONE_AREA_T:
        {
            const CPolyLine* outline = static_cast<const ZONE_CONTAINER*>( aItem )->Outline();
            int cornersCount = outline->GetCornersCount();

            SHAPE_LINE_CHAIN lc;
            lc.SetClosed( true );

            for( int i = 0; i < cornersCount; ++i )
            {
                const VECTOR2I p ( outline->GetPos( i ) );
                addAnchor( p, CORNER, aItem );
                lc.Append( p );
            }

            addAnchor( lc.NearestPoint( aRefPos ), OUTLINE, aItem );

            break;
        }

        case PCB_MODULE_TEXT_T:
        case PCB_TEXT_T:
            addAnchor( aItem->GetPosition(), ORIGIN, aItem );
        default:

        break;
   }
}
bool DIALOG_TRACK_VIA_PROPERTIES::TransferDataFromWindow()
{
    auto connectivity = m_frame->GetBoard()->GetConnectivity();
    int newNetCode = m_netSelector->GetSelectedNetcode();
    std::vector<D_PAD*> changingPads;

    if ( !m_netSelector->IsIndeterminate() )
    {
        std::set<D_PAD*> connectedPads;

        for( auto& item : m_items )
        {
            const KICAD_T ourTypes[] = { PCB_TRACE_T, PCB_PAD_T, PCB_VIA_T, PCB_MODULE_T, EOT };
            auto connectedItems = connectivity->GetConnectedItems( static_cast<BOARD_CONNECTED_ITEM*>( item ), ourTypes, true );
            for ( auto citem : connectedItems )
            {
                if( citem->Type() == PCB_PAD_T )
                {
                    connectedPads.insert( static_cast<D_PAD*>( citem ) );
                }
            }
        }

        for( D_PAD* pad : connectedPads )
        {
            if( pad->GetNetCode() != newNetCode )
                changingPads.push_back( pad );
        }
    }

    // Run validations:

    if( changingPads.size() )
    {
        if( !confirmPadChange( changingPads ) )
            return false;
    }

    if( m_vias )
    {
        if( !m_viaDiameter.Validate( GEOMETRY_MIN_SIZE, INT_MAX )
            || !m_viaDrill.Validate( GEOMETRY_MIN_SIZE, INT_MAX ) )
            return false;

        if( m_ViaDiameterCtrl->IsEnabled() && !m_viaDiameter.IsIndeterminate()
            && m_ViaDrillCtrl->IsEnabled() && !m_viaDrill.IsIndeterminate()
            && m_viaDiameter.GetValue() <= m_viaDrill.GetValue() )
        {
            DisplayError( GetParent(), _( "Via drill size must be smaller than via diameter" ) );
            m_ViaDrillCtrl->SelectAll();
            m_ViaDrillCtrl->SetFocus();
            return false;
        }

        if( m_ViaStartLayer->GetLayerSelection() != UNDEFINED_LAYER &&
            m_ViaStartLayer->GetLayerSelection() == m_ViaEndLayer->GetLayerSelection() )
        {
            DisplayError( GetParent(), _( "Via start layer and end layer cannot be the same" ) );
            return false;
        }
    }

    if( m_tracks )
    {
        if( !m_trackWidth.Validate( GEOMETRY_MIN_SIZE, INT_MAX ) )
            return false;
    }

    // If we survived that, then save the changes:

    bool changeLock = m_lockedCbox->Get3StateValue() != wxCHK_UNDETERMINED;
    bool setLock = m_lockedCbox->Get3StateValue() == wxCHK_CHECKED;

    for( auto item : m_items )
    {
        m_commit.Modify( item );

        switch( item->Type() )
        {
            case PCB_TRACE_T:
            {
                wxASSERT( m_tracks );
                TRACK* t = static_cast<TRACK*>( item );

                if( !m_trackStartX.IsIndeterminate() )
                    t->SetStart( wxPoint( m_trackStartX.GetValue(), t->GetStart().y ) );

                if( !m_trackStartY.IsIndeterminate() )
                    t->SetStart( wxPoint( t->GetStart().x, m_trackStartY.GetValue() ) );

                if( !m_trackEndX.IsIndeterminate() )
                    t->SetEnd( wxPoint( m_trackEndX.GetValue(), t->GetEnd().y ) );

                if( !m_trackEndY.IsIndeterminate() )
                    t->SetEnd( wxPoint( t->GetEnd().x, m_trackEndY.GetValue() ) );

                if( m_trackNetclass->IsChecked() )
                    t->SetWidth( t->GetNetClass()->GetTrackWidth() );
                else if( !m_trackWidth.IsIndeterminate() )
                    t->SetWidth( m_trackWidth.GetValue() );

                LAYER_NUM layer = m_TrackLayerCtrl->GetLayerSelection();

                if( layer != UNDEFINED_LAYER )
                    t->SetLayer( (PCB_LAYER_ID) layer );

                if( changeLock )
                    t->SetLocked( setLock );

                if ( !m_netSelector->IsIndeterminate() )
                    t->SetNetCode( m_netSelector->GetSelectedNetcode() );

                break;
            }

            case PCB_VIA_T:
            {
                wxASSERT( m_vias );
                VIA* v = static_cast<VIA*>( item );

                if( !m_viaX.IsIndeterminate() )
                    v->SetPosition( wxPoint( m_viaX.GetValue(), v->GetPosition().y ) );

                if( !m_viaY.IsIndeterminate() )
                    v->SetPosition( wxPoint( v->GetPosition().x, m_viaY.GetValue() ) );

                if( m_ViaTypeChoice->GetSelection() != 3)
                {
                    switch( m_ViaTypeChoice->GetSelection() )
                    {
                    default:
                    case 0: v->SetViaType( VIA_THROUGH ); v->SanitizeLayers(); break;
                    case 1: v->SetViaType( VIA_MICROVIA );                     break;
                    case 2: v->SetViaType( VIA_BLIND_BURIED );                 break;
                    }
                }

                auto startLayer = static_cast<PCB_LAYER_ID>( m_ViaStartLayer->GetLayerSelection() );
                auto endLayer = static_cast<PCB_LAYER_ID>( m_ViaEndLayer->GetLayerSelection() );

                if (startLayer != UNDEFINED_LAYER )
                    v->SetTopLayer( startLayer );

                if (endLayer != UNDEFINED_LAYER )
                    v->SetBottomLayer( endLayer );

                v->SanitizeLayers();

                if( m_viaNetclass->IsChecked() )
                {
                    switch( v->GetViaType() )
                    {
                    default:
                        wxFAIL_MSG("Unhandled via type");
                        // fall through

                    case VIA_THROUGH:
                    case VIA_BLIND_BURIED:
                        v->SetWidth( v->GetNetClass()->GetViaDiameter() );
                        v->SetDrill( v->GetNetClass()->GetViaDrill() );
                        break;

                    case VIA_MICROVIA:
                        v->SetWidth( v->GetNetClass()->GetuViaDiameter() );
                        v->SetDrill( v->GetNetClass()->GetuViaDrill() );
                        break;
                    }
                }
                else
                {
                    if( !m_viaDiameter.IsIndeterminate() )
                        v->SetWidth( m_viaDiameter.GetValue() );

                    if( !m_viaDrill.IsIndeterminate() )
                        v->SetDrill( m_viaDrill.GetValue() );
                }

                if ( !m_netSelector->IsIndeterminate() )
                    v->SetNetCode( m_netSelector->GetSelectedNetcode() );

                if( changeLock )
                    v->SetLocked( setLock );

                break;
            }

            default:
                wxASSERT( false );
                break;
        }
    }

    if ( !m_netSelector->IsIndeterminate() )
    {
        // Commit::Push() will rebuild connectivitiy propagating nets from connected pads
        // outwards.  We therefore have to update the connected pads in order for the net
        // change to "stick".
        for( D_PAD* pad : changingPads )
        {
            m_commit.Modify( pad );
            pad->SetNetCode( m_netSelector->GetSelectedNetcode() );
        }
    }

    m_commit.Push( _( "Edit track/via properties" ) );

    return true;
}
/* Init variables (slope, Y intersect point, flags) for
 * Show_Drag_Track_Segment_With_Cte_Slope()
 *  return true if Ok, false if dragging is not possible
 *  (2 colinear segments)
 */
bool InitialiseDragParameters()
{
    double     tx1, tx2, ty1, ty2; // temporary storage of points
    TRACK*     Track;
    TRACK*     tSegmentToStart = NULL, * tSegmentToEnd = NULL;

    if( g_DragSegmentList.size() == 0 )
        return false;

    /* get the segments :
     * from last to first in list are:
     * the segment to move
     * the segment connected to its end point (if exists)
     * the segment connected to its start point (if exists)
     */
    int ii = g_DragSegmentList.size() - 1;
    Track = g_DragSegmentList[ii].m_Track;
    if( Track == NULL )
        return false;

    ii--;

    if( ii >= 0)
    {
        if( s_EndSegmentPresent )
        {
            tSegmentToEnd = g_DragSegmentList[ii].m_Track;  // Get the segment connected to
                                                           // the end point
            ii--;
        }

        if( s_StartSegmentPresent )
        {
            if( ii  >= 0 )
                tSegmentToStart = g_DragSegmentList[ii].m_Track;  // Get the segment connected to
                                                                 // the start point
        }
    }

    // would be nice to eliminate collinear segments here, so we don't
    // have to deal with that annoying "Unable to drag this segment: two
    // collinear segments"

    s_StartPointVertical = false;
    s_EndPointVertical   = false;
    s_MovingSegmentVertical   = false;
    s_StartPointHorizontal    = false;
    s_EndPointHorizontal      = false;
    s_MovingSegmentHorizontal = false;

    // Init parameters for the starting point of the moved segment
    if( tSegmentToStart )
    {
        if( tSegmentToStart->GetFlags() & ENDPOINT )
        {
            tx1 = (double) tSegmentToStart->GetStart().x;
            ty1 = (double) tSegmentToStart->GetStart().y;
            tx2 = (double) tSegmentToStart->GetEnd().x;
            ty2 = (double) tSegmentToStart->GetEnd().y;
        }
        else
        {
            tx1 = (double) tSegmentToStart->GetEnd().x;
            ty1 = (double) tSegmentToStart->GetEnd().y;
            tx2 = (double) tSegmentToStart->GetStart().x;
            ty2 = (double) tSegmentToStart->GetStart().y;
        }
    }
    else // move the start point on a line starting at Track->GetStart(), and perpendicular to Track
    {
        tx1 = (double) Track->GetStart().x;
        ty1 = (double) Track->GetStart().y;
        tx2 = (double) Track->GetEnd().x;
        ty2 = (double) Track->GetEnd().y;
        RotatePoint( &tx2, &ty2, tx1, ty1, 900 );
    }

    if( tx1 != tx2 )
    {
        s_StartSegmentSlope = ( ty2 - ty1 ) / ( tx2 - tx1 );
        s_StartSegment_Yorg = ty1 - ( ty2 - ty1 ) * tx1 / ( tx2 - tx1 );
    }
    else
    {
        s_StartPointVertical = true;            //signal first segment vertical
    }

    if( ty1 == ty2 )
    {
        s_StartPointHorizontal = true;
    }

    // Init parameters for the ending point of the moved segment
    if( tSegmentToEnd )
    {
        //check if second line is vertical
        if( tSegmentToEnd->GetFlags() & STARTPOINT )
        {
            tx1 = (double) tSegmentToEnd->GetStart().x;
            ty1 = (double) tSegmentToEnd->GetStart().y;
            tx2 = (double) tSegmentToEnd->GetEnd().x;
            ty2 = (double) tSegmentToEnd->GetEnd().y;
        }
        else
        {
            tx1 = (double) tSegmentToEnd->GetEnd().x;
            ty1 = (double) tSegmentToEnd->GetEnd().y;
            tx2 = (double) tSegmentToEnd->GetStart().x;
            ty2 = (double) tSegmentToEnd->GetStart().y;
        }
    }
    else // move the start point on a line starting at Track->GetEnd(), and perpendicular to Track
    {
        tx1 = (double) Track->GetEnd().x;
        ty1 = (double) Track->GetEnd().y;
        tx2 = (double) Track->GetStart().x;
        ty2 = (double) Track->GetStart().y;
        RotatePoint( &tx2, &ty2, tx1, ty1, -900 );
    }

    if( tx2 != tx1 )
    {
        s_EndSegmentSlope = ( ty2 - ty1 ) / ( tx2 - tx1 );
        s_EndSegment_Yorg = ty1 - ( ty2 - ty1 ) * tx1 / ( tx2 - tx1 );
    }
    else
    {
        s_EndPointVertical = true;      //signal second segment vertical
    }

    if( ty1 == ty2 )
    {
        s_EndPointHorizontal = true;
    }

    // Init parameters for the moved segment
    tx1 = (double) Track->GetStart().x;
    ty1 = (double) Track->GetStart().y;
    tx2 = (double) Track->GetEnd().x;
    ty2 = (double) Track->GetEnd().y;

    if( tx2 != tx1 )
    {
        s_MovingSegmentSlope = ( ty2 - ty1 ) / ( tx2 - tx1 );
    }
    else
    {
        s_MovingSegmentVertical = true;      // signal vertical line
    }

    if( ty1 == ty2 )
    {
        s_MovingSegmentHorizontal = true;
    }

    // Test if drag is possible:
    if( s_MovingSegmentVertical )
    {
        if( s_EndPointVertical || s_StartPointVertical )
            return false;
    }
    else
    {
        if( !s_EndPointVertical && ( s_MovingSegmentSlope == s_EndSegmentSlope ) )
            return false;

        if( !s_StartPointVertical && ( s_MovingSegmentSlope == s_StartSegmentSlope ) )
            return false;
    }

    return true;
}
void BOARD_ITEM::SwapData( BOARD_ITEM* aImage )
{
    if( aImage == NULL )
    {
        return;
    }

    EDA_ITEM * pnext = Next();
    EDA_ITEM * pback = Back();

    switch( Type() )
    {
    case PCB_MODULE_T:
    {
        MODULE* tmp = (MODULE*) aImage->Clone();
        ( (MODULE*) aImage )->Copy( (MODULE*) this );
        ( (MODULE*) this )->Copy( tmp );
        delete tmp;
    }
        break;

    case PCB_ZONE_AREA_T:
    {
        ZONE_CONTAINER* tmp = (ZONE_CONTAINER*) aImage->Clone();
        ( (ZONE_CONTAINER*) aImage )->Copy( (ZONE_CONTAINER*) this );
        ( (ZONE_CONTAINER*) this )->Copy( tmp );
        delete tmp;
    }
        break;

    case PCB_LINE_T:
        std::swap( *((DRAWSEGMENT*)this), *((DRAWSEGMENT*)aImage) );
        break;

    case PCB_TRACE_T:
    case PCB_VIA_T:
    {
        TRACK* track = (TRACK*) this;
        TRACK* image = (TRACK*) aImage;

        EXCHG(track->m_Layer, image->m_Layer );

        // swap start, end, width and shape for track and image.
        wxPoint exchp = track->GetStart();
        track->SetStart( image->GetStart() );
        image->SetStart( exchp );
        exchp = track->GetEnd();
        track->SetEnd( image->GetEnd() );
        image->SetEnd( exchp );

        int atmp = track->GetWidth();
        track->SetWidth( image->GetWidth() );
        image->SetWidth( atmp );

        if( Type() == PCB_VIA_T )
        {
            VIA *via = static_cast<VIA*>( this );
            VIA *viaimage = static_cast<VIA*>( aImage );

            VIATYPE_T viatmp = via->GetViaType();
            via->SetViaType( viaimage->GetViaType() );
            viaimage->SetViaType( viatmp );

            int drilltmp = via->GetDrillValue();

            if( via->IsDrillDefault() )
                drilltmp = -1;

            int itmp = viaimage->GetDrillValue();

            if( viaimage->IsDrillDefault() )
                itmp = -1;

            EXCHG(itmp, drilltmp );

            if( drilltmp > 0 )
                via->SetDrill( drilltmp );
            else
                via->SetDrillDefault();

            if( itmp > 0 )
                viaimage->SetDrill( itmp );
            else
                viaimage->SetDrillDefault();
        }
    }
        break;

    case PCB_TEXT_T:
        std::swap( *((TEXTE_PCB*)this), *((TEXTE_PCB*)aImage) );
        break;

    case PCB_TARGET_T:
        std::swap( *((PCB_TARGET*)this), *((PCB_TARGET*)aImage) );
        break;

    case PCB_DIMENSION_T:
        std::swap( *((DIMENSION*)this), *((DIMENSION*)aImage) );
        break;

    case PCB_ZONE_T:
    default:
        wxLogMessage( wxT( "SwapData() error: unexpected type %d" ), Type() );
        break;
    }

    if( pnext != Next() || pback != Back() )
    {
        Pnext = pnext;
        Pback = pback;
#ifdef DEBUG
        wxLogMessage( wxT( "SwapData Error: %s Pnext or Pback pointers modified" ),
                      GetClass().GetData() );
#endif
    }
}