void CLAYER_TRIANGLES::AddToMiddleContourns( const SHAPE_POLY_SET &aPolySet,
float zBot,
float zTop,
double aBiuTo3Du,
bool aInvertFaceDirection )
{
wxASSERT( aPolySet.OutlineCount() > 0 );
if( aPolySet.OutlineCount() == 0 )
return;
// Calculate an estimation of points to reserve
unsigned int nrContournPointsToReserve = 0;
for( int i = 0; i < aPolySet.OutlineCount(); ++i )
{
const SHAPE_LINE_CHAIN& pathOutline = aPolySet.COutline( i );
nrContournPointsToReserve += pathOutline.PointCount();
for( int h = 0; h < aPolySet.HoleCount( i ); ++h )
{
const SHAPE_LINE_CHAIN &hole = aPolySet.CHole( i, h );
nrContournPointsToReserve += hole.PointCount();
}
}
// Request to reserve more space
m_layer_middle_contourns_quads->Reserve_More( nrContournPointsToReserve * 2,
true );
#pragma omp parallel for
for( signed int i = 0; i < aPolySet.OutlineCount(); ++i )
{
// Add outline
const SHAPE_LINE_CHAIN& pathOutline = aPolySet.COutline( i );
AddToMiddleContourns( pathOutline, zBot, zTop, aBiuTo3Du, aInvertFaceDirection );
// Add holes for this outline
for( int h = 0; h < aPolySet.HoleCount( i ); ++h )
{
const SHAPE_LINE_CHAIN &hole = aPolySet.CHole( i, h );
AddToMiddleContourns( hole, zBot, zTop, aBiuTo3Du, aInvertFaceDirection );
}
}
}
/* Build a pad outline as non filled polygon, to draw pads on silkscreen layer
* Used only to draw pads outlines on silkscreen layers.
*/
void EDA_3D_CANVAS::buildPadShapeThickOutlineAsPolygon( const D_PAD* aPad,
SHAPE_POLY_SET& aCornerBuffer,
int aWidth,
int aCircleToSegmentsCount,
double aCorrectionFactor )
{
if( aPad->GetShape() == PAD_SHAPE_CIRCLE ) // Draw a ring
{
TransformRingToPolygon( aCornerBuffer, aPad->ShapePos(),
aPad->GetSize().x / 2, aCircleToSegmentsCount, aWidth );
return;
}
// For other shapes, draw polygon outlines
SHAPE_POLY_SET corners;
aPad->BuildPadShapePolygon( corners, wxSize( 0, 0 ),
aCircleToSegmentsCount, aCorrectionFactor );
// Add outlines as thick segments in polygon buffer
const SHAPE_LINE_CHAIN& path = corners.COutline( 0 );
for( int ii = 0; ii < path.PointCount(); ii++ )
{
const VECTOR2I& a = path.CPoint( ii );
const VECTOR2I& b = path.CPoint( ii + 1 );
TransformRoundedEndsSegmentToPolygon( aCornerBuffer,
wxPoint( a.x, a.y ),
wxPoint( b.x, b.y ),
aCircleToSegmentsCount, aWidth );
}
}
void DXF_PLOTTER::ThickSegment( const wxPoint& aStart, const wxPoint& aEnd, int aWidth,
EDA_DRAW_MODE_T aPlotMode, void* aData )
{
if( aPlotMode == SKETCH )
{
std::vector<wxPoint> cornerList;
SHAPE_POLY_SET outlineBuffer;
TransformOvalClearanceToPolygon( outlineBuffer,
aStart, aEnd, aWidth, 32 , 1.0 );
const SHAPE_LINE_CHAIN& path = outlineBuffer.COutline(0 );
for( int jj = 0; jj < path.PointCount(); jj++ )
cornerList.push_back( wxPoint( path.CPoint( jj ).x , path.CPoint( jj ).y ) );
// Ensure the polygon is closed
if( cornerList[0] != cornerList[cornerList.size() - 1] )
cornerList.push_back( cornerList[0] );
PlotPoly( cornerList, NO_FILL );
}
else
{
MoveTo( aStart );
FinishTo( aEnd );
}
}
void CINFO3D_VISU::buildPadShapeThickOutlineAsPolygon( const D_PAD* aPad,
SHAPE_POLY_SET& aCornerBuffer,
int aWidth ) const
{
if( aPad->GetShape() == PAD_SHAPE_CIRCLE ) // Draw a ring
{
unsigned int nr_sides_per_circle = GetNrSegmentsCircle( ( aPad->GetSize().x / 2 +
aWidth / 2 ) * 2 );
TransformRingToPolygon( aCornerBuffer, aPad->ShapePos(),
aPad->GetSize().x / 2, nr_sides_per_circle, aWidth );
return;
}
// For other shapes, draw polygon outlines
SHAPE_POLY_SET corners;
unsigned int nr_sides_per_circle = GetNrSegmentsCircle( glm::min( aPad->GetSize().x,
aPad->GetSize().y) );
buildPadShapePolygon( aPad, corners, wxSize( 0, 0 ),
nr_sides_per_circle, GetCircleCorrectionFactor( nr_sides_per_circle ) );
// Add outlines as thick segments in polygon buffer
const SHAPE_LINE_CHAIN& path = corners.COutline( 0 );
for( int ii = 0; ii < path.PointCount(); ++ii )
{
const VECTOR2I& a = path.CPoint( ii );
const VECTOR2I& b = path.CPoint( ii + 1 );
TransformRoundedEndsSegmentToPolygon( aCornerBuffer,
wxPoint( a.x, a.y ),
wxPoint( b.x, b.y ),
nr_sides_per_circle,
aWidth );
}
}
bool D_PAD::HitTest( const wxPoint& aPosition ) const
{
int dx, dy;
wxPoint shape_pos = ShapePos();
wxPoint delta = aPosition - shape_pos;
// first test: a test point must be inside a minimum sized bounding circle.
int radius = GetBoundingRadius();
if( ( abs( delta.x ) > radius ) || ( abs( delta.y ) > radius ) )
return false;
dx = m_Size.x >> 1; // dx also is the radius for rounded pads
dy = m_Size.y >> 1;
switch( GetShape() )
{
case PAD_SHAPE_CIRCLE:
if( KiROUND( EuclideanNorm( delta ) ) <= dx )
return true;
break;
case PAD_SHAPE_TRAPEZOID:
{
wxPoint poly[4];
BuildPadPolygon( poly, wxSize(0,0), 0 );
RotatePoint( &delta, -m_Orient );
return TestPointInsidePolygon( poly, 4, delta );
}
case PAD_SHAPE_OVAL:
{
RotatePoint( &delta, -m_Orient );
// An oval pad has the same shape as a segment with rounded ends
// After rotation, the test point is relative to an horizontal pad
int dist;
wxPoint offset;
if( dy > dx ) // shape is a vertical oval
{
offset.y = dy - dx;
dist = dx;
}
else //if( dy <= dx ) shape is an horizontal oval
{
offset.x = dy - dx;
dist = dy;
}
return TestSegmentHit( delta, - offset, offset, dist );
}
break;
case PAD_SHAPE_RECT:
RotatePoint( &delta, -m_Orient );
if( (abs( delta.x ) <= dx ) && (abs( delta.y ) <= dy) )
return true;
break;
case PAD_SHAPE_ROUNDRECT:
{
// Check for hit in polygon
SHAPE_POLY_SET outline;
const int segmentToCircleCount = 32;
TransformRoundRectToPolygon( outline, wxPoint(0,0), GetSize(), m_Orient,
GetRoundRectCornerRadius(), segmentToCircleCount );
const SHAPE_LINE_CHAIN &poly = outline.COutline( 0 );
return TestPointInsidePolygon( (const wxPoint*)&poly.CPoint(0), poly.PointCount(), delta );
}
break;
case PAD_SHAPE_CUSTOM:
// Check for hit in polygon
RotatePoint( &delta, -m_Orient );
if( m_customShapeAsPolygon.OutlineCount() )
{
const SHAPE_LINE_CHAIN& poly = m_customShapeAsPolygon.COutline( 0 );
return TestPointInsidePolygon( (const wxPoint*)&poly.CPoint(0), poly.PointCount(), delta );
}
break;
}
return false;
}
/* test DRC between 2 pads.
* this function can be also used to test DRC between a pad and a hole,
* because a hole is like a round or oval pad.
*/
bool DRC::checkClearancePadToPad( D_PAD* aRefPad, D_PAD* aPad )
{
int dist;
double pad_angle;
// Get the clearance between the 2 pads. this is the min distance between aRefPad and aPad
int dist_min = aRefPad->GetClearance( aPad );
// relativePadPos is the aPad shape position relative to the aRefPad shape position
wxPoint relativePadPos = aPad->ShapePos() - aRefPad->ShapePos();
dist = KiROUND( EuclideanNorm( relativePadPos ) );
// Quick test: Clearance is OK if the bounding circles are further away than "dist_min"
if( (dist - aRefPad->GetBoundingRadius() - aPad->GetBoundingRadius()) >= dist_min )
return true;
/* Here, pads are near and DRC depend on the pad shapes
* We must compare distance using a fine shape analysis
* Because a circle or oval shape is the easier shape to test, try to have
* aRefPad shape type = PAD_SHAPE_CIRCLE or PAD_SHAPE_OVAL.
* if aRefPad = TRAP. and aPad = RECT, also swap pads
* Swap aRefPad and aPad if needed
*/
bool swap_pads;
swap_pads = false;
// swap pads to make comparisons easier
// Note also a ROUNDRECT pad with a corner radius = r can be considered as
// a smaller RECT (size - 2*r) with a clearance increased by r
// priority is aRefPad = ROUND then OVAL then RECT/ROUNDRECT then other
if( aRefPad->GetShape() != aPad->GetShape() && aRefPad->GetShape() != PAD_SHAPE_CIRCLE )
{
// pad ref shape is here oval, rect, roundrect, trapezoid or custom
switch( aPad->GetShape() )
{
case PAD_SHAPE_CIRCLE:
swap_pads = true;
break;
case PAD_SHAPE_OVAL:
swap_pads = true;
break;
case PAD_SHAPE_RECT:
case PAD_SHAPE_ROUNDRECT:
if( aRefPad->GetShape() != PAD_SHAPE_OVAL )
swap_pads = true;
break;
default:
break;
}
}
if( swap_pads )
{
std::swap( aRefPad, aPad );
relativePadPos = -relativePadPos;
}
// corners of aRefPad (used only for rect/roundrect/trap pad)
wxPoint polyref[4];
// corners of aRefPad (used only for custom pad)
SHAPE_POLY_SET polysetref;
// corners of aPad (used only for rect/roundrect/trap pad)
wxPoint polycompare[4];
// corners of aPad (used only custom pad)
SHAPE_POLY_SET polysetcompare;
/* Because pad exchange, aRefPad shape is PAD_SHAPE_CIRCLE or PAD_SHAPE_OVAL,
* if one of the 2 pads was a PAD_SHAPE_CIRCLE or PAD_SHAPE_OVAL.
* Therefore, if aRefPad is a PAD_SHAPE_RECT, PAD_SHAPE_ROUNDRECT or a PAD_SHAPE_TRAPEZOID,
* aPad is also a PAD_SHAPE_RECT, PAD_SHAPE_ROUNDRECT or a PAD_SHAPE_TRAPEZOID
*/
bool diag = true;
switch( aRefPad->GetShape() )
{
case PAD_SHAPE_CIRCLE:
/* One can use checkClearanceSegmToPad to test clearance
* aRefPad is like a track segment with a null length and a witdth = GetSize().x
*/
m_segmLength = 0;
m_segmAngle = 0;
m_segmEnd.x = m_segmEnd.y = 0;
m_padToTestPos = relativePadPos;
diag = checkClearanceSegmToPad( aPad, aRefPad->GetSize().x, dist_min );
break;
case PAD_SHAPE_TRAPEZOID:
case PAD_SHAPE_ROUNDRECT:
case PAD_SHAPE_RECT:
// pad_angle = pad orient relative to the aRefPad orient
pad_angle = aRefPad->GetOrientation() + aPad->GetOrientation();
NORMALIZE_ANGLE_POS( pad_angle );
if( aRefPad->GetShape() == PAD_SHAPE_ROUNDRECT )
{
int padRadius = aRefPad->GetRoundRectCornerRadius();
dist_min += padRadius;
GetRoundRectCornerCenters( polyref, padRadius, wxPoint( 0, 0 ),
aRefPad->GetSize(), aRefPad->GetOrientation() );
}
else
aRefPad->BuildPadPolygon( polyref, wxSize( 0, 0 ), aRefPad->GetOrientation() );
switch( aPad->GetShape() )
{
case PAD_SHAPE_ROUNDRECT:
case PAD_SHAPE_RECT:
case PAD_SHAPE_TRAPEZOID:
if( aPad->GetShape() == PAD_SHAPE_ROUNDRECT )
{
int padRadius = aPad->GetRoundRectCornerRadius();
dist_min += padRadius;
GetRoundRectCornerCenters( polycompare, padRadius, relativePadPos,
aPad->GetSize(), aPad->GetOrientation() );
}
else
{
aPad->BuildPadPolygon( polycompare, wxSize( 0, 0 ), aPad->GetOrientation() );
// Move aPad shape to relativePadPos
for( int ii = 0; ii < 4; ii++ )
polycompare[ii] += relativePadPos;
}
// And now test polygons:
if( polysetref.OutlineCount() )
{
const SHAPE_LINE_CHAIN& refpoly = polysetref.COutline( 0 );
// And now test polygons:
if( !poly2polyDRC( (wxPoint*) &refpoly.CPoint( 0 ), refpoly.PointCount(),
polycompare, 4, dist_min ) )
diag = false;
}
else if( !poly2polyDRC( polyref, 4, polycompare, 4, dist_min ) )
diag = false;
break;
default:
wxLogDebug( wxT( "DRC::checkClearancePadToPad: unexpected pad shape %d" ), aPad->GetShape() );
break;
}
break;
case PAD_SHAPE_OVAL: /* an oval pad is like a track segment */
{
/* Create a track segment with same dimensions as the oval aRefPad
* and use checkClearanceSegmToPad function to test aPad to aRefPad clearance
*/
int segm_width;
m_segmAngle = aRefPad->GetOrientation(); // Segment orient.
if( aRefPad->GetSize().y < aRefPad->GetSize().x ) // Build an horizontal equiv segment
{
segm_width = aRefPad->GetSize().y;
m_segmLength = aRefPad->GetSize().x - aRefPad->GetSize().y;
}
else // Vertical oval: build an horizontal equiv segment and rotate 90.0 deg
{
segm_width = aRefPad->GetSize().x;
m_segmLength = aRefPad->GetSize().y - aRefPad->GetSize().x;
m_segmAngle += 900;
}
/* the start point must be 0,0 and currently relativePadPos
* is relative the center of pad coordinate */
wxPoint segstart;
segstart.x = -m_segmLength / 2; // Start point coordinate of the horizontal equivalent segment
RotatePoint( &segstart, m_segmAngle ); // actual start point coordinate of the equivalent segment
// Calculate segment end position relative to the segment origin
m_segmEnd.x = -2 * segstart.x;
m_segmEnd.y = -2 * segstart.y;
// Recalculate the equivalent segment angle in 0,1 degrees
// to prepare a call to checkClearanceSegmToPad()
m_segmAngle = ArcTangente( m_segmEnd.y, m_segmEnd.x );
// move pad position relative to the segment origin
m_padToTestPos = relativePadPos - segstart;
// Use segment to pad check to test the second pad:
diag = checkClearanceSegmToPad( aPad, segm_width, dist_min );
break;
}
default:
wxLogDebug( wxT( "DRC::checkClearancePadToPad: unknown pad shape" ) );
break;
}
return diag;
}
bool ZONE_FILLER::fillZoneWithSegments( const ZONE_CONTAINER* aZone,
const SHAPE_POLY_SET& aFilledPolys,
ZONE_SEGMENT_FILL& aFillSegs ) const
{
bool success = true;
// segments are on something like a grid. Give it a minimal size
// to avoid too many segments, and use the m_ZoneMinThickness when (this is usually the case)
// the size is > mingrid_size.
// This is not perfect, but the actual purpose of this code
// is to allow filling zones on a grid, with grid size > m_ZoneMinThickness,
// in order to have really a grid.
//
// Using a user selectable grid size is for future Kicad versions.
// For now the area is fully filled.
int mingrid_size = Millimeter2iu( 0.05 );
int grid_size = std::max( mingrid_size, aZone->GetMinThickness() );
// Make segments slightly overlapping to ensure a good full filling
grid_size -= grid_size/20;
// Creates the horizontal segments
for ( int index = 0; index < aFilledPolys.OutlineCount(); index++ )
{
const SHAPE_LINE_CHAIN& outline0 = aFilledPolys.COutline( index );
success = fillPolygonWithHorizontalSegments( outline0, aFillSegs, grid_size );
if( !success )
break;
// Creates the vertical segments. Because the filling algo creates horizontal segments,
// to reuse the fillPolygonWithHorizontalSegments function, we rotate the polygons to fill
// then fill them, then inverse rotate the result
SHAPE_LINE_CHAIN outline90;
outline90.Append( outline0 );
// Rotate 90 degrees the outline:
for( int ii = 0; ii < outline90.PointCount(); ii++ )
{
VECTOR2I& point = outline90.Point( ii );
std::swap( point.x, point.y );
point.y = -point.y;
}
int first_point = aFillSegs.size();
success = fillPolygonWithHorizontalSegments( outline90, aFillSegs, grid_size );
if( !success )
break;
// Rotate -90 degrees the segments:
for( unsigned ii = first_point; ii < aFillSegs.size(); ii++ )
{
SEG& segm = aFillSegs[ii];
std::swap( segm.A.x, segm.A.y );
std::swap( segm.B.x, segm.B.y );
segm.A.x = - segm.A.x;
segm.B.x = - segm.B.x;
}
}
return success;
}
void Convert_shape_line_polygon_to_triangles( const SHAPE_POLY_SET &aPolyList,
CGENERICCONTAINER2D &aDstContainer,
float aBiuTo3DunitsScale ,
const BOARD_ITEM &aBoardItem )
{
unsigned int nOutlines = aPolyList.OutlineCount();
for( unsigned int idx = 0; idx < nOutlines; ++idx )
{
const SHAPE_LINE_CHAIN &outlinePath = aPolyList.COutline( idx );
wxASSERT( outlinePath.PointCount() >= 3 );
std::vector<SFVEC2I64> scaledOutline;
scaledOutline.resize( outlinePath.PointCount() );
// printf("\nidx: %u\n", idx);
// Apply a scale to the points
for( unsigned int i = 0;
i < (unsigned int)outlinePath.PointCount();
++i )
{
const VECTOR2I& a = outlinePath.CPoint( i );
#ifdef APPLY_EDGE_SHRINK
scaledOutline[i] = SFVEC2I64( (glm::int64)a.x * POLY_SCALE_FACT,
(glm::int64)a.y * POLY_SCALE_FACT );
#else
scaledOutline[i] = SFVEC2I64( (glm::int64)a.x,
(glm::int64)a.y );
#endif
}
#ifdef APPLY_EDGE_SHRINK
// Apply a modification to the points
EdgeShrink( scaledOutline );
#endif
// Copy to a array of pointers
std::vector<p2t::Point*> polyline;
polyline.resize( outlinePath.PointCount() );
for( unsigned int i = 0;
i < (unsigned int)scaledOutline.size();
++i )
{
const SFVEC2I64 &a = scaledOutline[i];
//printf("%lu %lu\n", a.x, a.y);
polyline[i] = new p2t::Point( (double)a.x,
(double)a.y );
}
// Start creating the structured to be triangulated
p2t::CDT* cdt = new p2t::CDT( polyline );
// Add holes for this outline
unsigned int nHoles = aPolyList.HoleCount( idx );
std::vector< std::vector<p2t::Point*> > polylineHoles;
polylineHoles.resize( nHoles );
for( unsigned int idxHole = 0; idxHole < nHoles; ++idxHole )
{
const SHAPE_LINE_CHAIN &outlineHoles = aPolyList.CHole( idx,
idxHole );
wxASSERT( outlineHoles.PointCount() >= 3 );
std::vector<SFVEC2I64> scaledHole;
scaledHole.resize( outlineHoles.PointCount() );
// Apply a scale to the points
for( unsigned int i = 0;
i < (unsigned int)outlineHoles.PointCount();
++i )
{
const VECTOR2I &h = outlineHoles.CPoint( i );
#ifdef APPLY_EDGE_SHRINK
scaledHole[i] = SFVEC2I64( (glm::int64)h.x * POLY_SCALE_FACT,
(glm::int64)h.y * POLY_SCALE_FACT );
#else
scaledHole[i] = SFVEC2I64( (glm::int64)h.x,
(glm::int64)h.y );
#endif
}
#ifdef APPLY_EDGE_SHRINK
// Apply a modification to the points
EdgeShrink( scaledHole );
#endif
// Resize and reserve space
polylineHoles[idxHole].resize( outlineHoles.PointCount() );
for( unsigned int i = 0;
i < (unsigned int)outlineHoles.PointCount();
++i )
{
const SFVEC2I64 &h = scaledHole[i];
polylineHoles[idxHole][i] = new p2t::Point( h.x, h.y );
}
cdt->AddHole( polylineHoles[idxHole] );
}
// Triangulate
cdt->Triangulate();
// Hint: if you find any crashes on the triangulation poly2tri library,
// you can use the following site to debug the points and it will mark
// the errors in the polygon:
// http://r3mi.github.io/poly2tri.js/
// Get and add triangles
std::vector<p2t::Triangle*> triangles;
triangles = cdt->GetTriangles();
#ifdef APPLY_EDGE_SHRINK
const double conver_d = (double)aBiuTo3DunitsScale *
POLY_SCALE_FACT_INVERSE;
#else
const double conver_d = (double)aBiuTo3DunitsScale;
#endif
for( unsigned int i = 0; i < triangles.size(); ++i )
{
p2t::Triangle& t = *triangles[i];
p2t::Point& a = *t.GetPoint( 0 );
p2t::Point& b = *t.GetPoint( 1 );
p2t::Point& c = *t.GetPoint( 2 );
aDstContainer.Add( new CTRIANGLE2D( SFVEC2F( a.x * conver_d,
-a.y * conver_d ),
SFVEC2F( b.x * conver_d,
-b.y * conver_d ),
SFVEC2F( c.x * conver_d,
-c.y * conver_d ),
aBoardItem ) );
}
// Delete created data
delete cdt;
// Free points
FreeClear(polyline);
for( unsigned int idxHole = 0; idxHole < nHoles; ++idxHole )
{
FreeClear( polylineHoles[idxHole] );
}
}
}
bool D_PAD::GetBestAnchorPosition( VECTOR2I& aPos )
{
SHAPE_POLY_SET poly;
if( !buildCustomPadPolygon( &poly, ARC_LOW_DEF ) )
return false;
const int minSteps = 10;
const int maxSteps = 50;
int stepsX, stepsY;
auto bbox = poly.BBox();
if( bbox.GetWidth() < bbox.GetHeight() )
{
stepsX = minSteps;
stepsY = minSteps * (double) bbox.GetHeight() / (double )(bbox.GetWidth() + 1);
}
else
{
stepsY = minSteps;
stepsX = minSteps * (double) bbox.GetWidth() / (double )(bbox.GetHeight() + 1);
}
stepsX = std::max(minSteps, std::min( maxSteps, stepsX ) );
stepsY = std::max(minSteps, std::min( maxSteps, stepsY ) );
auto center = bbox.Centre();
auto minDist = std::numeric_limits<int64_t>::max();
int64_t minDistEdge;
if( GetAnchorPadShape() == PAD_SHAPE_CIRCLE )
{
minDistEdge = GetSize().x;
}
else
{
minDistEdge = std::max( GetSize().x, GetSize().y );
}
OPT<VECTOR2I> bestAnchor( []()->OPT<VECTOR2I> { return NULLOPT; }() );
for ( int y = 0; y < stepsY ; y++ )
{
for ( int x = 0; x < stepsX; x++ )
{
VECTOR2I p = bbox.GetPosition();
p.x += rescale( x, bbox.GetWidth(), (stepsX - 1) );
p.y += rescale( y, bbox.GetHeight(), (stepsY - 1) );
if ( poly.Contains(p) )
{
auto dist = (center - p).EuclideanNorm();
auto distEdge = poly.COutline(0).Distance( p, true );
if ( distEdge >= minDistEdge )
{
if ( dist < minDist )
{
bestAnchor = p;
minDist = dist;
}
}
}
}
}
if ( bestAnchor )
{
aPos = *bestAnchor;
return true;
}
return false;
}
/**
* DXF polygon: doesn't fill it but at least it close the filled ones
* DXF does not know thick outline.
* It does not know thhick segments, therefore filled polygons with thick outline
* are converted to inflated polygon by aWidth/2
*/
void DXF_PLOTTER::PlotPoly( const std::vector<wxPoint>& aCornerList,
FILL_T aFill, int aWidth)
{
if( aCornerList.size() <= 1 )
return;
unsigned last = aCornerList.size() - 1;
// Plot outlines with lines (thickness = 0) to define the polygon
if( aWidth <= 0 )
{
MoveTo( aCornerList[0] );
for( unsigned ii = 1; ii < aCornerList.size(); ii++ )
LineTo( aCornerList[ii] );
// Close polygon if 'fill' requested
if( aFill )
{
if( aCornerList[last] != aCornerList[0] )
LineTo( aCornerList[0] );
}
PenFinish();
return;
}
// if the polygon outline has thickness, and is not filled
// (i.e. is a polyline) plot outlines with thick segments
if( aWidth > 0 && !aFill )
{
MoveTo( aCornerList[0] );
for( unsigned ii = 1; ii < aCornerList.size(); ii++ )
ThickSegment( aCornerList[ii-1], aCornerList[ii],
aWidth, FILLED );
return;
}
// The polygon outline has thickness, and is filled
// Build and plot the polygon which contains the initial
// polygon and its thick outline
SHAPE_POLY_SET bufferOutline;
SHAPE_POLY_SET bufferPolybase;
const int circleToSegmentsCount = 16;
bufferPolybase.NewOutline();
// enter outline as polygon:
for( unsigned ii = 1; ii < aCornerList.size(); ii++ )
{
TransformRoundedEndsSegmentToPolygon( bufferOutline,
aCornerList[ii-1], aCornerList[ii], circleToSegmentsCount, aWidth );
}
// enter the initial polygon:
for( unsigned ii = 0; ii < aCornerList.size(); ii++ )
{
bufferPolybase.Append( aCornerList[ii] );
}
// Merge polygons to build the polygon which contains the initial
// polygon and its thick outline
bufferPolybase.BooleanAdd( bufferOutline ); // create the outline which contains thick outline
bufferPolybase.Fracture();
if( bufferPolybase.OutlineCount() < 1 ) // should not happen
return;
const SHAPE_LINE_CHAIN& path = bufferPolybase.COutline( 0 );
if( path.PointCount() < 2 ) // should not happen
return;
// Now, output the final polygon to DXF file:
last = path.PointCount() - 1;
VECTOR2I point = path.CPoint( 0 );
wxPoint startPoint( point.x, point.y );
MoveTo( startPoint );
for( int ii = 1; ii < path.PointCount(); ii++ )
{
point = path.CPoint( ii );
LineTo( wxPoint( point.x, point.y ) );
}
// Close polygon, if needed
point = path.CPoint( last );
wxPoint endPoint( point.x, point.y );
if( endPoint != startPoint )
LineTo( startPoint );
PenFinish();
}
void C3D_RENDER_OGL_LEGACY::reload()
{
m_reloadRequested = false;
ogl_free_all_display_lists();
COBJECT2D_STATS::Instance().ResetStats();
m_settings.InitSettings();
SFVEC3F camera_pos = m_settings.GetBoardCenter3DU();
m_settings.CameraGet().SetBoardLookAtPos( camera_pos );
// Create Board
// /////////////////////////////////////////////////////////////////////////
printf("Create board...\n");
CCONTAINER2D boardContainer;
Convert_shape_line_polygon_to_triangles( m_settings.GetBoardPoly(),
boardContainer,
m_settings.BiuTo3Dunits(),
(const BOARD_ITEM &)*m_settings.GetBoard() );
const LIST_OBJECT2D listBoardObject2d = boardContainer.GetList();
if( listBoardObject2d.size() > 0 )
{
/*
float layer_z_top = m_settings.GetLayerBottomZpos3DU( F_Cu );
float layer_z_bot = m_settings.GetLayerBottomZpos3DU( B_Cu );
*/
float layer_z_top = m_settings.GetLayerBottomZpos3DU( B_Mask );
float layer_z_bot = m_settings.GetLayerTopZpos3DU( B_Mask );
CLAYER_TRIANGLES *layerTriangles = new CLAYER_TRIANGLES( listBoardObject2d.size() );
for( LIST_OBJECT2D::const_iterator itemOnLayer = listBoardObject2d.begin();
itemOnLayer != listBoardObject2d.end();
itemOnLayer++ )
{
const COBJECT2D *object2d_A = static_cast<const COBJECT2D *>(*itemOnLayer);
wxASSERT( object2d_A->GetObjectType() == OBJ2D_TRIANGLE );
const CTRIANGLE2D *tri = (const CTRIANGLE2D *)object2d_A;
const SFVEC2F &v1 = tri->GetP1();
const SFVEC2F &v2 = tri->GetP2();
const SFVEC2F &v3 = tri->GetP3();
add_triangle_top_bot( layerTriangles, v1, v2, v3, layer_z_top, layer_z_bot );
}
const SHAPE_POLY_SET boardPoly = m_settings.GetBoardPoly();
SHAPE_POLY_SET boardPolyCopy = boardPoly;
boardPolyCopy.Simplify( SHAPE_POLY_SET::PM_FAST );
if( boardPolyCopy.OutlineCount() == 1 )
{
const SHAPE_LINE_CHAIN& outlinePath = boardPolyCopy.COutline( 0 );
std::vector< SFVEC2F > contournPoints;
contournPoints.clear();
contournPoints.reserve( outlinePath.PointCount() + 2 );
for( unsigned int i = 0; i < (unsigned int)outlinePath.PointCount(); ++i )
{
const VECTOR2I& v = outlinePath.CPoint( i );
contournPoints.push_back( SFVEC2F( v.x * m_settings.BiuTo3Dunits(),
-v.y * m_settings.BiuTo3Dunits() ) );
}
contournPoints.push_back( contournPoints[0] );
if( contournPoints.size() > 4 )
{
// Calculate normals of each segment of the contourn
std::vector< SFVEC2F > contournNormals;
contournNormals.clear();
contournNormals.reserve( contournPoints.size() );
for( unsigned int i = 0; i < ( contournPoints.size() - 1 ); ++i )
{
const SFVEC2F &v0 = contournPoints[i + 0];
const SFVEC2F &v1 = contournPoints[i + 1];
SFVEC2F n = glm::normalize( v1 - v0 );
contournNormals.push_back( SFVEC2F( -n.y, n.x ) );
}
SFVEC2F lastNormal = contournNormals[contournPoints.size() - 2];
for( unsigned int i = 0; i < ( contournPoints.size() - 1 ); ++i )
{
const SFVEC2F &v0 = contournPoints[i + 0];
const SFVEC2F &v1 = contournPoints[i + 1];
layerTriangles->m_layer_middle_contourns_quads->AddQuad( SFVEC3F( v0.x, v0.y, NextFloatUp( layer_z_top ) ),
SFVEC3F( v1.x, v1.y, NextFloatUp( layer_z_top ) ),
SFVEC3F( v1.x, v1.y, NextFloatDown( layer_z_bot ) ),
SFVEC3F( v0.x, v0.y, NextFloatDown( layer_z_bot ) ) );
SFVEC2F n0 = contournNormals[i];
if( glm::dot( n0, lastNormal ) > 0.5f )
n0 += lastNormal;
else
n0 += contournNormals[i];
const SFVEC2F &nextNormal = contournNormals[ (i + 1) % (contournPoints.size() - 1) ];
SFVEC2F n1 = contournNormals[i];
if( glm::dot( n1, nextNormal ) > 0.5f )
n1 += nextNormal;
else
n1 += contournNormals[i];
n0 = glm::normalize( n0 );
n1 = glm::normalize( n1 );
const SFVEC3F n3d0 = SFVEC3F( n0.x, n0.y, 0.0f );
const SFVEC3F n3d1 = SFVEC3F( n1.x, n1.y, 0.0f );
layerTriangles->m_layer_middle_contourns_quads->AddNormal( n3d0, n3d1, n3d1, n3d0 );
lastNormal = contournNormals[i];
/*
const SFVEC2F n0 = glm::normalize( v0 - center );
const SFVEC2F n1 = glm::normalize( v1 - center );
const SFVEC3F n0z = SFVEC3F( n0.x, n0.y, 0.0f );
const SFVEC3F n1z = SFVEC3F( n1.x, n1.y, 0.0f );
layerTriangles->m_layer_middle_contourns_quads->AddNormal( n0z, n1z, n1z, n0z );*/
}
}
contournPoints.clear();
}
m_ogl_disp_list_board = new CLAYERS_OGL_DISP_LISTS( *layerTriangles, m_ogl_circle_texture, SFVEC3F(0.65f,0.55f,0.05f) );
delete layerTriangles;
}
float calc_sides_min_factor = (float)( 10.0 * IU_PER_MILS * m_settings.BiuTo3Dunits() );
float calc_sides_max_factor = (float)( 1000.0 * IU_PER_MILS * m_settings.BiuTo3Dunits() );
// Add layers maps (except B_Mask and F_Mask)
// /////////////////////////////////////////////////////////////////////////
printf("Add layers maps...\n");
for( MAP_CONTAINER_2D::const_iterator it = m_settings.GetMapLayers().begin();
it != m_settings.GetMapLayers().end(); it++ )
{
LAYER_ID layer_id = static_cast<LAYER_ID>(it->first);
if( !m_settings.Is3DLayerEnabled( layer_id ) )
continue;
const CBVHCONTAINER2D *container2d = static_cast<const CBVHCONTAINER2D *>(it->second);
const LIST_OBJECT2D listObject2d = container2d->GetList();
if( listObject2d.size() == 0 )
continue;
//CMATERIAL *materialLayer = &m_materials.m_SilkS;
SFVEC3F layerColor = SFVEC3F( 0.3f, 0.4f, 0.5f );
float layer_z_bot = m_settings.GetLayerBottomZpos3DU( layer_id );
float layer_z_top = m_settings.GetLayerTopZpos3DU( layer_id );
if( layer_z_top < layer_z_bot )
{
float tmpFloat = layer_z_bot;
layer_z_bot = layer_z_top;
layer_z_top = tmpFloat;
}
layer_z_bot -= m_settings.GetNonCopperLayerThickness3DU();
layer_z_top += m_settings.GetNonCopperLayerThickness3DU();
if( m_settings.GetFlag( FL_USE_REALISTIC_MODE ) )
{
switch( layer_id )
{
case B_Adhes:
case F_Adhes:
break;
case B_Paste:
case F_Paste:
// materialLayer = &m_materials.m_Paste;
break;
case B_SilkS:
case F_SilkS:
// materialLayer = &m_materials.m_SilkS;
// layerColor = g_silkscreenColor;
break;
case Dwgs_User:
case Cmts_User:
case Eco1_User:
case Eco2_User:
case Edge_Cuts:
case Margin:
break;
case B_CrtYd:
case F_CrtYd:
break;
case B_Fab:
case F_Fab:
break;
default:
//materialLayer = &m_materials.m_Copper;
//layerColor = g_copperColor;
break;
}
}
else
{
layerColor = m_settings.GetLayerColor( layer_id );
}
// Calculate an estiation for then nr of triangles based on the nr of objects
unsigned int nrTrianglesEstimation = listObject2d.size() * 8;
CLAYER_TRIANGLES *layerTriangles = new CLAYER_TRIANGLES( nrTrianglesEstimation );
m_triangles[layer_id] = layerTriangles;
for( LIST_OBJECT2D::const_iterator itemOnLayer = listObject2d.begin();
itemOnLayer != listObject2d.end(); itemOnLayer++ )
{
const COBJECT2D *object2d_A = static_cast<const COBJECT2D *>(*itemOnLayer);
switch( object2d_A->GetObjectType() )
{
case OBJ2D_FILLED_CIRCLE:
{
const CFILLEDCIRCLE2D *filledCircle = (const CFILLEDCIRCLE2D *)object2d_A;
const SFVEC2F ¢er = filledCircle->GetCenter();
float radius = filledCircle->GetRadius() * 2.0f; // Double because the render triangle
float radiusSquared = radius * radius;
const float f = (sqrtf(2.0f) / 2.0f) * radius * 0.9;// * texture_factor;
layerTriangles->m_layer_top_segment_ends->AddTriangle( SFVEC3F( center.x + f, center.y, layer_z_top ),
SFVEC3F( center.x - f, center.y, layer_z_top ),
SFVEC3F( center.x,
center.y - f, layer_z_top ) );
layerTriangles->m_layer_top_segment_ends->AddTriangle( SFVEC3F( center.x - f, center.y, layer_z_top ),
SFVEC3F( center.x + f, center.y, layer_z_top ),
SFVEC3F( center.x,
center.y + f, layer_z_top ) );
layerTriangles->m_layer_bot_segment_ends->AddTriangle( SFVEC3F( center.x - f, center.y, layer_z_bot ),
SFVEC3F( center.x + f, center.y, layer_z_bot ),
SFVEC3F( center.x,
center.y - f, layer_z_bot ) );
layerTriangles->m_layer_bot_segment_ends->AddTriangle( SFVEC3F( center.x + f, center.y, layer_z_bot ),
SFVEC3F( center.x - f, center.y, layer_z_bot ),
SFVEC3F( center.x,
center.y + f, layer_z_bot ) );
unsigned int nr_sides_per_circle = (unsigned int)mapf( radiusSquared,
calc_sides_min_factor, calc_sides_max_factor,
24.0f, 256.0f );
wxASSERT( nr_sides_per_circle >= 24 );
// Normal radius for the circle
radius = filledCircle->GetRadius();
std::vector< SFVEC2F > contournPoints;
contournPoints.clear();
contournPoints.reserve( nr_sides_per_circle + 2 );
int delta = 3600 / nr_sides_per_circle;
for( int ii = 0; ii < 3600; ii += delta )
{
const SFVEC2F rotatedDir = glm::rotate( SFVEC2F( 0.0f, 1.0f ), (float)ii * 2.0f * 3.14f / 3600.0f );
contournPoints.push_back( SFVEC2F( center.x - rotatedDir.y * radius, center.y + rotatedDir.x * radius ) );
}
contournPoints.push_back( contournPoints[0] );
if( contournPoints.size() > 1 )
{
for( unsigned int i = 0; i < ( contournPoints.size() - 1 ); ++i )
{
const SFVEC2F &v0 = contournPoints[i + 0];
const SFVEC2F &v1 = contournPoints[i + 1];
layerTriangles->m_layer_middle_contourns_quads->AddQuad( SFVEC3F( v0.x, v0.y, NextFloatUp( layer_z_bot ) ),
SFVEC3F( v1.x, v1.y, NextFloatUp( layer_z_bot ) ),
SFVEC3F( v1.x, v1.y, NextFloatDown( layer_z_top ) ),
SFVEC3F( v0.x, v0.y, NextFloatDown( layer_z_top ) ) );
const SFVEC2F n0 = glm::normalize( v0 - center );
const SFVEC2F n1 = glm::normalize( v1 - center );
const SFVEC3F n0z = SFVEC3F( n0.x, n0.y, 0.0f );
const SFVEC3F n1z = SFVEC3F( n1.x, n1.y, 0.0f );
layerTriangles->m_layer_middle_contourns_quads->AddNormal( n0z, n1z, n1z, n0z );
}
}
contournPoints.clear();
}
break;
case OBJ2D_DUMMYBLOCK:
{
}
break;
case OBJ2D_POLYGON4PT:
{
const CPOLYGON4PTS2D *poly = (const CPOLYGON4PTS2D *)object2d_A;
const SFVEC2F &v0 = poly->GetV0();
const SFVEC2F &v1 = poly->GetV1();
const SFVEC2F &v2 = poly->GetV2();
const SFVEC2F &v3 = poly->GetV3();
add_triangle_top_bot( layerTriangles, v0, v2, v1, layer_z_top, layer_z_bot );
add_triangle_top_bot( layerTriangles, v2, v0, v3, layer_z_top, layer_z_bot );
const SFVEC2F &n0 = poly->GetN0();
const SFVEC2F &n1 = poly->GetN1();
const SFVEC2F &n2 = poly->GetN2();
const SFVEC2F &n3 = poly->GetN3();
const SFVEC3F n3d0 = SFVEC3F(-n0.y, n0.x, 0.0f );
const SFVEC3F n3d1 = SFVEC3F(-n1.y, n1.x, 0.0f );
const SFVEC3F n3d2 = SFVEC3F(-n2.y, n2.x, 0.0f );
const SFVEC3F n3d3 = SFVEC3F(-n3.y, n3.x, 0.0f );
layerTriangles->m_layer_middle_contourns_quads->AddQuad( SFVEC3F( v0.x, v0.y, layer_z_bot ),
SFVEC3F( v1.x, v1.y, layer_z_bot ),
SFVEC3F( v1.x, v1.y, layer_z_top ),
SFVEC3F( v0.x, v0.y, layer_z_top ) );
layerTriangles->m_layer_middle_contourns_quads->AddNormal( n3d0, n3d0, n3d0, n3d0 );
layerTriangles->m_layer_middle_contourns_quads->AddQuad( SFVEC3F( v2.x, v2.y, layer_z_top ),
SFVEC3F( v1.x, v1.y, layer_z_top ),
SFVEC3F( v1.x, v1.y, layer_z_bot ),
SFVEC3F( v2.x, v2.y, layer_z_bot ) );
layerTriangles->m_layer_middle_contourns_quads->AddNormal( n3d1, n3d1, n3d1, n3d1 );
layerTriangles->m_layer_middle_contourns_quads->AddQuad( SFVEC3F( v3.x, v3.y, layer_z_top ),
SFVEC3F( v2.x, v2.y, layer_z_top ),
SFVEC3F( v2.x, v2.y, layer_z_bot ),
SFVEC3F( v3.x, v3.y, layer_z_bot ) );
layerTriangles->m_layer_middle_contourns_quads->AddNormal( n3d2, n3d2, n3d2, n3d2 );
layerTriangles->m_layer_middle_contourns_quads->AddQuad( SFVEC3F( v0.x, v0.y, layer_z_top ),
SFVEC3F( v3.x, v3.y, layer_z_top ),
SFVEC3F( v3.x, v3.y, layer_z_bot ),
SFVEC3F( v0.x, v0.y, layer_z_bot ) );
layerTriangles->m_layer_middle_contourns_quads->AddNormal( n3d3, n3d3, n3d3, n3d3 );
}
break;
case OBJ2D_RING:
{
const CRING2D *ring = (const CRING2D *)object2d_A;
const SFVEC2F ¢er = ring->GetCenter();
float inner = ring->GetInnerRadius();
float outer = ring->GetOuterRadius();
unsigned int nr_sides_per_circle = (unsigned int)mapf( outer,
calc_sides_min_factor, calc_sides_max_factor,
24.0f, 256.0f );
wxASSERT( nr_sides_per_circle >= 24 );
std::vector< SFVEC2F > innerContour;
std::vector< SFVEC2F > outerContour;
innerContour.clear();
innerContour.reserve( nr_sides_per_circle + 2 );
outerContour.clear();
outerContour.reserve( nr_sides_per_circle + 2 );
int delta = 3600 / nr_sides_per_circle;
for( int ii = 0; ii < 3600; ii += delta )
{
const SFVEC2F rotatedDir = glm::rotate( SFVEC2F( 0.0f, 1.0f), (float) ii * 2.0f * 3.14f / 3600.0f );
innerContour.push_back( SFVEC2F( center.x - rotatedDir.y * inner, center.y + rotatedDir.x * inner ) );
outerContour.push_back( SFVEC2F( center.x - rotatedDir.y * outer, center.y + rotatedDir.x * outer ) );
}
innerContour.push_back( innerContour[0] );
outerContour.push_back( outerContour[0] );
wxASSERT( innerContour.size() == outerContour.size() );
for( unsigned int i = 0; i < ( innerContour.size() - 1 ); ++i )
{
const SFVEC2F &vi0 = innerContour[i + 0];
const SFVEC2F &vi1 = innerContour[i + 1];
const SFVEC2F &vo0 = outerContour[i + 0];
const SFVEC2F &vo1 = outerContour[i + 1];
layerTriangles->m_layer_top_triangles->AddQuad( SFVEC3F( vi1.x, vi1.y, layer_z_top ),
SFVEC3F( vi0.x, vi0.y, layer_z_top ),
SFVEC3F( vo0.x, vo0.y, layer_z_top ),
SFVEC3F( vo1.x, vo1.y, layer_z_top ) );
layerTriangles->m_layer_bot_triangles->AddQuad( SFVEC3F( vi1.x, vi1.y, layer_z_bot ),
SFVEC3F( vo1.x, vo1.y, layer_z_bot ),
SFVEC3F( vo0.x, vo0.y, layer_z_bot ),
SFVEC3F( vi0.x, vi0.y, layer_z_bot ) );
}
for( unsigned int i = 0; i < ( innerContour.size() - 1 ); ++i )
{
const SFVEC2F &v0 = innerContour[i + 0];
const SFVEC2F &v1 = innerContour[i + 1];
layerTriangles->m_layer_middle_contourns_quads->AddQuad( SFVEC3F( v1.x, v1.y, NextFloatUp( layer_z_bot ) ),
SFVEC3F( v0.x, v0.y, NextFloatUp( layer_z_bot ) ),
SFVEC3F( v0.x, v0.y, NextFloatDown( layer_z_top ) ),
SFVEC3F( v1.x, v1.y, NextFloatDown( layer_z_top ) ) );
const SFVEC2F n0 = glm::normalize( v0 - center );
const SFVEC2F n1 = glm::normalize( v1 - center );
const SFVEC3F n0z = SFVEC3F( n0.x, n0.y, 0.0f );
const SFVEC3F n1z = SFVEC3F( n1.x, n1.y, 0.0f );
layerTriangles->m_layer_middle_contourns_quads->AddNormal( n0z, n1z, n1z, n0z );
}
for( unsigned int i = 0; i < ( outerContour.size() - 1 ); ++i )
{
const SFVEC2F &v0 = outerContour[i + 0];
const SFVEC2F &v1 = outerContour[i + 1];
layerTriangles->m_layer_middle_contourns_quads->AddQuad( SFVEC3F( v0.x, v0.y, NextFloatUp( layer_z_bot ) ),
SFVEC3F( v1.x, v1.y, NextFloatUp( layer_z_bot ) ),
SFVEC3F( v1.x, v1.y, NextFloatDown( layer_z_top ) ),
SFVEC3F( v0.x, v0.y, NextFloatDown( layer_z_top ) ) );
const SFVEC2F n0 = glm::normalize( v0 - center );
const SFVEC2F n1 = glm::normalize( v1 - center );
const SFVEC3F n0z = SFVEC3F( n0.x, n0.y, 0.0f );
const SFVEC3F n1z = SFVEC3F( n1.x, n1.y, 0.0f );
layerTriangles->m_layer_middle_contourns_quads->AddNormal( n0z, n1z, n1z, n0z );
}
}
break;
case OBJ2D_TRIANGLE:
{
const CTRIANGLE2D *tri = (const CTRIANGLE2D *)object2d_A;
const SFVEC2F &v1 = tri->GetP1();
const SFVEC2F &v2 = tri->GetP2();
const SFVEC2F &v3 = tri->GetP3();
add_triangle_top_bot( layerTriangles, v1, v2, v3, layer_z_top, layer_z_bot );
}
break;
case OBJ2D_ROUNDSEG:
{
const CROUNDSEGMENT2D &roundSeg = (const CROUNDSEGMENT2D &) *object2d_A;
unsigned int nr_sides_per_circle = (unsigned int)mapf( roundSeg.GetWidth(),
calc_sides_min_factor, calc_sides_max_factor,
24.0f, 256.0f );
wxASSERT( nr_sides_per_circle >= 24 );
SFVEC2F leftStart = roundSeg.GetLeftStar();
SFVEC2F leftEnd = roundSeg.GetLeftEnd();
SFVEC2F leftDir = roundSeg.GetLeftDir();
SFVEC2F rightStart = roundSeg.GetRightStar();
SFVEC2F rightEnd = roundSeg.GetRightEnd();
SFVEC2F rightDir = roundSeg.GetRightDir();
float radius = roundSeg.GetRadius();
SFVEC2F start = roundSeg.GetStart();
SFVEC2F end = roundSeg.GetEnd();
float texture_factor = (12.0f/(float)SIZE_OF_CIRCLE_TEXTURE) + 1.0f;
float texture_factorF= ( 4.0f/(float)SIZE_OF_CIRCLE_TEXTURE) + 1.0f;
const float radius_of_the_square = sqrtf( roundSeg.GetRadiusSquared() * 2.0f );
const float radius_triangle_factor = (radius_of_the_square - radius) / radius;
const SFVEC2F factorS = SFVEC2F( -rightDir.y * radius * radius_triangle_factor, rightDir.x * radius * radius_triangle_factor );
const SFVEC2F factorE = SFVEC2F( -leftDir.y * radius * radius_triangle_factor, leftDir.x * radius * radius_triangle_factor );
// Top end segment triangles
layerTriangles->m_layer_top_segment_ends->AddTriangle( SFVEC3F( rightEnd.x + texture_factor * factorS.x, rightEnd.y + texture_factor * factorS.y, layer_z_top ),
SFVEC3F( leftStart.x + texture_factor * factorE.x, leftStart.y + texture_factor * factorE.y, layer_z_top ),
SFVEC3F( start.x - texture_factorF * leftDir.x * radius * sqrtf(2.0f),
start.y - texture_factorF * leftDir.y * radius * sqrtf(2.0f), layer_z_top ) );
layerTriangles->m_layer_top_segment_ends->AddTriangle( SFVEC3F( leftEnd.x + texture_factor * factorE.x, leftEnd.y + texture_factor * factorE.y, layer_z_top ),
SFVEC3F( rightStart.x + texture_factor * factorS.x, rightStart.y + texture_factor * factorS.y, layer_z_top ),
SFVEC3F( end.x - texture_factorF * rightDir.x * radius * sqrtf(2.0f),
end.y - texture_factorF * rightDir.y * radius * sqrtf(2.0f), layer_z_top ) );
// Bot end segment triangles
layerTriangles->m_layer_bot_segment_ends->AddTriangle( SFVEC3F( leftStart.x + texture_factor * factorE.x, leftStart.y + texture_factor * factorE.y, layer_z_bot ),
SFVEC3F( rightEnd.x + texture_factor * factorS.x, rightEnd.y + texture_factor * factorS.y, layer_z_bot ),
SFVEC3F( start.x - texture_factorF * leftDir.x * radius * sqrtf(2.0f),
start.y - texture_factorF * leftDir.y * radius * sqrtf(2.0f), layer_z_bot ) );
layerTriangles->m_layer_bot_segment_ends->AddTriangle( SFVEC3F( rightStart.x + texture_factor * factorS.x, rightStart.y + texture_factor * factorS.y, layer_z_bot ),
SFVEC3F( leftEnd.x + texture_factor * factorE.x, leftEnd.y + texture_factor * factorE.y, layer_z_bot ),
SFVEC3F( end.x - texture_factorF * rightDir.x * radius * sqrtf(2.0f),
end.y - texture_factorF * rightDir.y * radius * sqrtf(2.0f), layer_z_bot ) );
// Segment top and bot planes
layerTriangles->m_layer_top_triangles->AddQuad( SFVEC3F( rightEnd.x, rightEnd.y, layer_z_top ),
SFVEC3F( rightStart.x, rightStart.y, layer_z_top ),
SFVEC3F( leftEnd.x, leftEnd.y, layer_z_top ),
SFVEC3F( leftStart.x, leftStart.y, layer_z_top ) );
layerTriangles->m_layer_bot_triangles->AddQuad( SFVEC3F( rightEnd.x, rightEnd.y, layer_z_bot ),
SFVEC3F( leftStart.x, leftStart.y, layer_z_bot ),
SFVEC3F( leftEnd.x, leftEnd.y, layer_z_bot ),
SFVEC3F( rightStart.x, rightStart.y, layer_z_bot ) );
// Middle contourns (two sides of the segment)
layerTriangles->m_layer_middle_contourns_quads->AddQuad( SFVEC3F( leftStart.x, leftStart.y, layer_z_top ),
SFVEC3F( leftEnd.x, leftEnd.y, layer_z_top ),
SFVEC3F( leftEnd.x, leftEnd.y, layer_z_bot ),
SFVEC3F( leftStart.x, leftStart.y, layer_z_bot ) );
const SFVEC3F leftNormal = SFVEC3F( -leftDir.y, leftDir.x, 0.0f );
layerTriangles->m_layer_middle_contourns_quads->AddNormal( leftNormal, leftNormal, leftNormal, leftNormal );
layerTriangles->m_layer_middle_contourns_quads->AddQuad( SFVEC3F( rightStart.x, rightStart.y, layer_z_top ),
SFVEC3F( rightEnd.x, rightEnd.y, layer_z_top ),
SFVEC3F( rightEnd.x, rightEnd.y, layer_z_bot ),
SFVEC3F( rightStart.x, rightStart.y, layer_z_bot ) );
const SFVEC3F rightNormal = SFVEC3F( -rightDir.y, rightDir.x, 0.0f );
layerTriangles->m_layer_middle_contourns_quads->AddNormal( rightNormal, rightNormal, rightNormal, rightNormal );
// Compute the outlines of the segment, and creates a polygon
// add right rounded end:
std::vector< SFVEC2F > roundedEndPointsStart;
std::vector< SFVEC2F > roundedEndPointsEnd;
roundedEndPointsStart.clear();
roundedEndPointsStart.reserve( nr_sides_per_circle + 2 );
roundedEndPointsEnd.clear();
roundedEndPointsEnd.reserve( nr_sides_per_circle + 2 );
roundedEndPointsStart.push_back( SFVEC2F( leftStart.x, leftStart.y ) );
roundedEndPointsEnd.push_back( SFVEC2F( leftEnd.x, leftEnd.y ) );
int delta = 3600 / nr_sides_per_circle;
for( int ii = delta; ii < 1800; ii += delta )
{
const SFVEC2F rotatedDirL = glm::rotate( leftDir, (float) ii * 2.0f * 3.14f / 3600.0f );
const SFVEC2F rotatedDirR = glm::rotate( rightDir, (float)(1800 - ii) * 2.0f * 3.14f / 3600.0f );
roundedEndPointsStart.push_back( SFVEC2F( start.x - rotatedDirL.y * radius, start.y + rotatedDirL.x * radius ) );
roundedEndPointsEnd.push_back( SFVEC2F( end.x - rotatedDirR.y * radius, end.y + rotatedDirR.x * radius ) );
}
roundedEndPointsStart.push_back( SFVEC2F( rightEnd.x, rightEnd.y ) );
roundedEndPointsEnd.push_back( SFVEC2F( rightStart.x, rightStart.y ) );
if( roundedEndPointsStart.size() > 1 )
{
for( unsigned int i = 0; i < ( roundedEndPointsStart.size() - 1 ); ++i )
{
const SFVEC2F &v0 = roundedEndPointsStart[i + 0];
const SFVEC2F &v1 = roundedEndPointsStart[i + 1];
layerTriangles->m_layer_middle_contourns_quads->AddQuad( SFVEC3F( v0.x, v0.y, layer_z_bot ),
SFVEC3F( v1.x, v1.y, layer_z_bot ),
SFVEC3F( v1.x, v1.y, layer_z_top ),
SFVEC3F( v0.x, v0.y, layer_z_top ) );
const SFVEC2F n0 = glm::normalize( v0 - start );
const SFVEC2F n1 = glm::normalize( v1 - start );
const SFVEC3F n0z = SFVEC3F( n0.x, n0.y, 0.0f );
const SFVEC3F n1z = SFVEC3F( n1.x, n1.y, 0.0f );
layerTriangles->m_layer_middle_contourns_quads->AddNormal( n0z, n1z, n1z, n0z );
}
}
roundedEndPointsStart.clear();
if( roundedEndPointsEnd.size() > 1 )
{
for( unsigned int i = 0; i < ( roundedEndPointsEnd.size() - 1 ); ++i )
{
const SFVEC2F &v0 = roundedEndPointsEnd[i + 0];
const SFVEC2F &v1 = roundedEndPointsEnd[i + 1];
layerTriangles->m_layer_middle_contourns_quads->AddQuad( SFVEC3F( v0.x, v0.y, layer_z_top ),
SFVEC3F( v1.x, v1.y, layer_z_top ),
SFVEC3F( v1.x, v1.y, layer_z_bot ),
SFVEC3F( v0.x, v0.y, layer_z_bot ) );
const SFVEC2F n0 = glm::normalize( v0 - end );
const SFVEC2F n1 = glm::normalize( v1 - end );
const SFVEC3F n0z = SFVEC3F( n0.x, n0.y, 0.0f );
const SFVEC3F n1z = SFVEC3F( n1.x, n1.y, 0.0f );
layerTriangles->m_layer_middle_contourns_quads->AddNormal( n0z, n1z, n1z, n0z );
}
}
roundedEndPointsEnd.clear();
}
break;
default:
{
}
break;
}
#if 0
// not yet used / implemented (can be used in future to clip the objects in the board borders
COBJECT2D *object2d_C = CSGITEM_FULL;
std::vector<const COBJECT2D *> *object2d_B = CSGITEM_EMPTY;
if( m_settings.GetFlag( FL_RENDER_SHOW_HOLES_IN_ZONES ) )
{
object2d_B = new std::vector<const COBJECT2D *>();
// Check if there are any layerhole that intersects this object
// Eg: a segment is cutted by a via hole or THT hole.
// /////////////////////////////////////////////////////////////
const MAP_CONTAINER_2D &layerHolesMap = m_settings.GetMapLayersHoles();
if( layerHolesMap.find(layer_id) != layerHolesMap.end() )
{
MAP_CONTAINER_2D::const_iterator ii_hole = layerHolesMap.find(layer_id);
const CBVHCONTAINER2D *containerLayerHoles2d = static_cast<const CBVHCONTAINER2D *>(ii_hole->second);
CONST_LIST_OBJECT2D intersectionList;
containerLayerHoles2d->GetListObjectsIntersects( object2d_A->GetBBox(), intersectionList );
if( !intersectionList.empty() )
{
for( CONST_LIST_OBJECT2D::const_iterator holeOnLayer = intersectionList.begin();
holeOnLayer != intersectionList.end();
holeOnLayer++ )
{
const COBJECT2D *hole2d = static_cast<const COBJECT2D *>(*holeOnLayer);
//if( object2d_A->Intersects( hole2d->GetBBox() ) )
//if( object2d_A->GetBBox().Intersects( hole2d->GetBBox() ) )
object2d_B->push_back( hole2d );
}
}
}
// Check if there are any THT that intersects this object
// /////////////////////////////////////////////////////////////
if( !m_settings.GetThroughHole_Inflated().GetList().empty() )
{
CONST_LIST_OBJECT2D intersectionList;
m_settings.GetThroughHole_Inflated().GetListObjectsIntersects( object2d_A->GetBBox(), intersectionList );
if( !intersectionList.empty() )
{
for( CONST_LIST_OBJECT2D::const_iterator hole = intersectionList.begin();
hole != intersectionList.end();
hole++ )
{
const COBJECT2D *hole2d = static_cast<const COBJECT2D *>(*hole);
//if( object2d_A->Intersects( hole2d->GetBBox() ) )
//if( object2d_A->GetBBox().Intersects( hole2d->GetBBox() ) )
object2d_B->push_back( hole2d );
}
}
}
if( object2d_B->empty() )
{
delete object2d_B;
object2d_B = CSGITEM_EMPTY;
}
}
if( (object2d_B == CSGITEM_EMPTY) &&
(object2d_C == CSGITEM_FULL) )
{
#if 0
create_3d_object_from( m_object_container, object2d_A, m_settings.GetLayerBottomZpos3DU( layer_id ),
m_settings.GetLayerTopZpos3DU( layer_id ),
materialLayer,
layerColor );
#else
CLAYERITEM *objPtr = new CLAYERITEM( object2d_A, m_settings.GetLayerBottomZpos3DU( layer_id ),
m_settings.GetLayerTopZpos3DU( layer_id ) );
objPtr->SetMaterial( materialLayer );
objPtr->SetColor( layerColor );
m_object_container.Add( objPtr );
#endif
}
else
{
#if 1
CITEMLAYERCSG2D *itemCSG2d = new CITEMLAYERCSG2D( object2d_A, object2d_B, object2d_C,
object2d_A->GetBoardItem() );
m_containerWithObjectsToDelete.Add( itemCSG2d );
CLAYERITEM *objPtr = new CLAYERITEM( itemCSG2d, m_settings.GetLayerBottomZpos3DU( layer_id ),
m_settings.GetLayerTopZpos3DU( layer_id ) );
objPtr->SetMaterial( materialLayer );
objPtr->SetColor( layerColor );
m_object_container.Add( objPtr );
#endif
}
#endif
}
// Create display list
// /////////////////////////////////////////////////////////////////////
m_ogl_disp_lists_layers[layer_id] = new CLAYERS_OGL_DISP_LISTS( *layerTriangles,
m_ogl_circle_texture,
layerColor );
}// for each layer on map
}
/* Plot outlines of copper, for copper layer
*/
void PlotLayerOutlines( BOARD* aBoard, PLOTTER* aPlotter,
LSET aLayerMask, const PCB_PLOT_PARAMS& aPlotOpt )
{
BRDITEMS_PLOTTER itemplotter( aPlotter, aBoard, aPlotOpt );
itemplotter.SetLayerSet( aLayerMask );
SHAPE_POLY_SET outlines;
for( LSEQ seq = aLayerMask.Seq( plot_seq, DIM( plot_seq ) ); seq; ++seq )
{
LAYER_ID layer = *seq;
outlines.RemoveAllContours();
aBoard->ConvertBrdLayerToPolygonalContours( layer, outlines );
outlines.Simplify();
// Plot outlines
std::vector< wxPoint > cornerList;
// Now we have one or more basic polygons: plot each polygon
for( int ii = 0; ii < outlines.OutlineCount(); ii++ )
{
for(int kk = 0; kk <= outlines.HoleCount (ii); kk++ )
{
cornerList.clear();
const SHAPE_LINE_CHAIN& path = (kk == 0) ? outlines.COutline( ii ) : outlines.CHole( ii, kk - 1 );
for( int jj = 0; jj < path.PointCount(); jj++ )
cornerList.push_back( wxPoint( path.CPoint( jj ).x , path.CPoint( jj ).y ) );
// Ensure the polygon is closed
if( cornerList[0] != cornerList[cornerList.size() - 1] )
cornerList.push_back( cornerList[0] );
aPlotter->PlotPoly( cornerList, NO_FILL );
}
}
// Plot pad holes
if( aPlotOpt.GetDrillMarksType() != PCB_PLOT_PARAMS::NO_DRILL_SHAPE )
{
for( MODULE* module = aBoard->m_Modules; module; module = module->Next() )
{
for( D_PAD* pad = module->Pads(); pad; pad = pad->Next() )
{
wxSize hole = pad->GetDrillSize();
if( hole.x == 0 || hole.y == 0 )
continue;
if( hole.x == hole.y )
aPlotter->Circle( pad->GetPosition(), hole.x, NO_FILL );
else
{
wxPoint drl_start, drl_end;
int width;
pad->GetOblongDrillGeometry( drl_start, drl_end, width );
aPlotter->ThickSegment( pad->GetPosition() + drl_start,
pad->GetPosition() + drl_end, width, SKETCH );
}
}
}
}
// Plot vias holes
for( TRACK* track = aBoard->m_Track; track; track = track->Next() )
{
const VIA* via = dyn_cast<const VIA*>( track );
if( via && via->IsOnLayer( layer ) ) // via holes can be not through holes
{
aPlotter->Circle( via->GetPosition(), via->GetDrillValue(), NO_FILL );
}
}
}
}
