kicad/pcbnew/teardrop/teardrop_utils.cpp

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/*
* This program source code file is part of KiCad, a free EDA CAD application.
*
* Copyright (C) 2021 Jean-Pierre Charras, jp.charras at wanadoo.fr
* Copyright (C) 2022 KiCad Developers, see AUTHORS.txt for contributors.
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, you may find one here:
* http://www.gnu.org/licenses/old-licenses/gpl-2.0.html
* or you may search the http://www.gnu.org website for the version 2 license,
* or you may write to the Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA
*/
/*
* Some calculations (mainly computeCurvedForRoundShape) are derived from
* https://github.com/NilujePerchut/kicad_scripts/tree/master/teardrops
*/
#include <board_design_settings.h>
#include <pcb_track.h>
#include <pad.h>
#include <zone_filler.h>
#include <board_commit.h>
#include "teardrop.h"
#include <geometry/convex_hull.h>
#include <geometry/shape_line_chain.h>
#include <convert_basic_shapes_to_polygon.h>
#include <bezier_curves.h>
#include <wx/log.h>
void TRACK_BUFFER::AddTrack( PCB_TRACK* aTrack, int aLayer, int aNetcode )
{
auto item = m_map_tracks.find( idxFromLayNet( aLayer, aNetcode ) );
std::vector<PCB_TRACK*>* buffer;
if( item == m_map_tracks.end() )
{
buffer = new std::vector<PCB_TRACK*>;
m_map_tracks[idxFromLayNet( aLayer, aNetcode )] = buffer;
}
else
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{
buffer = (*item).second;
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}
buffer->push_back( aTrack );
}
VIAPAD::VIAPAD( PCB_VIA* aVia ) :
m_Parent( aVia )
{
m_Pos = aVia->GetPosition();
m_Width = aVia->GetWidth();
m_Drill = aVia->GetDrillValue();
m_NetCode = aVia->GetNetCode();
m_IsRound = true;
m_IsPad = false;
}
VIAPAD::VIAPAD( PAD* aPad ) :
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m_Parent( aPad )
{
m_Pos = aPad->GetPosition();
m_Width = std::min( aPad->GetSize().x, aPad->GetSize().y );
m_Drill = std::min( aPad->GetDrillSizeX(), aPad->GetDrillSizeY() );
m_NetCode = aPad->GetNetCode();
m_IsRound = aPad->GetShape() == PAD_SHAPE::CIRCLE ||
( aPad->GetShape() == PAD_SHAPE::OVAL
&& aPad->GetSize().x == aPad->GetSize().y );
m_IsPad = true;
}
VIAPAD::VIAPAD( PCB_TRACK* aTrack, ENDPOINT_T aEndPoint ) :
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m_Parent( aTrack )
{
m_Pos = aEndPoint == ENDPOINT_START ? aTrack->GetStart() : aTrack->GetEnd();
m_Width =aTrack->GetWidth();
m_Drill = 0;
m_NetCode = aTrack->GetNetCode();
m_IsRound = true;
m_IsPad = false;
}
void TEARDROP_MANAGER::collectVias( std::vector< VIAPAD >& aList ) const
{
for( PCB_TRACK* item : m_board->Tracks() )
{
if( item->Type() != PCB_VIA_T )
continue;
aList.emplace_back( static_cast<PCB_VIA*>( item ) );
}
}
void TEARDROP_MANAGER::collectPadsCandidate( std::vector< VIAPAD >& aList,
bool aDrilledViaPad,
bool aRoundShapesOnly,
bool aIncludeNotDrilled ) const
{
for( FOOTPRINT* fp : m_board->Footprints() )
{
for( PAD* pad : fp->Pads() )
{
if( !pad->IsOnCopperLayer() )
continue;
if( pad->GetNetCode() <= 0 ) // Not connected, so a teardrop cannot be attached
continue;
if( pad->GetShape() == PAD_SHAPE::CUSTOM ) // A teardrop shape cannot be built
continue;
if( aRoundShapesOnly )
{
bool round_shape = pad->GetShape() == PAD_SHAPE::CIRCLE
|| ( pad->GetShape() == PAD_SHAPE::OVAL
&& pad->GetSize().x == pad->GetSize().y );
if( !round_shape )
continue;
}
if( pad->HasHole() && !aDrilledViaPad )
continue;
if( pad->HasHole() || aIncludeNotDrilled )
aList.emplace_back( pad );
}
}
}
void TEARDROP_MANAGER::collectTeardrops( std::vector< ZONE* >& aList ) const
{
for( ZONE* zone : m_board->Zones() )
{
if( zone->IsTeardropArea() )
aList.push_back( zone );
}
}
bool TEARDROP_MANAGER::isViaAndTrackInSameZone( VIAPAD& aViapad, PCB_TRACK* aTrack ) const
{
for( ZONE* zone: m_board->Zones() )
{
// Skip teardrops
if( zone->IsTeardropArea() )
continue;
// Only consider zones on the same layer
if( !zone->IsOnLayer( aTrack->GetLayer() ) )
continue;
if( zone->GetNetCode() == aTrack->GetNetCode() )
{
if( zone->Outline()->Contains( VECTOR2I( aViapad.m_Pos ) ) )
{
// Ensure the pad (if it is a pad) can be connected by the zone
if( aViapad.m_IsPad )
{
PAD *pad = static_cast< PAD* >( aViapad.m_Parent );
if( zone->GetPadConnection() == ZONE_CONNECTION::NONE
|| pad->GetZoneConnection() == ZONE_CONNECTION::NONE )
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{
return false;
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}
}
return true;
}
}
}
return false;
}
PCB_TRACK* TEARDROP_MANAGER::findTouchingTrack( EDA_ITEM_FLAGS& aMatchType, PCB_TRACK* aTrackRef,
const VECTOR2I& aEndPoint,
TRACK_BUFFER& aTrackLookupList ) const
{
EDA_ITEM_FLAGS match = 0; // to return the end point EDA_ITEM_FLAGS:
// 0, STARTPOINT, ENDPOINT
int matches = 0; // Count of candidates: only 1 is acceptable
PCB_TRACK* candidate = nullptr; // a reference to the track connected
std::vector<PCB_TRACK*>* currlist = aTrackLookupList.GetTrackList( aTrackRef->GetLayer(),
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aTrackRef->GetNetCode() );
for( PCB_TRACK* curr_track: *currlist )
{
if( curr_track == aTrackRef )
continue;
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match = curr_track->IsPointOnEnds( aEndPoint, m_tolerance);
if( match )
{
// if faced with a Y junction, choose the track longest segment as candidate
matches++;
if( matches > 1 )
{
double previous_len = candidate->GetLength();
double curr_len = curr_track->GetLength();
if( previous_len >= curr_len )
continue;
}
aMatchType = match;
candidate = curr_track;
}
}
return candidate;
}
/**
* @return a vector unit length from aVector
*/
static VECTOR2D NormalizeVector( VECTOR2I aVector )
{
VECTOR2D vect( aVector );
double norm = vect.EuclideanNorm();
return vect / norm;
}
/*
* Compute the curve part points for teardrops connected to a round shape
* The Bezier curve control points are optimized for a round pad/via shape,
* and do not give a good curve shape for other pad shapes
*/
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void TEARDROP_MANAGER::computeCurvedForRoundShape( TEARDROP_PARAMETERS* aCurrParams,
std::vector<VECTOR2I>& aPoly,
int aTrackHalfWidth,
VECTOR2D aTrackDir, VIAPAD& aViaPad,
std::vector<VECTOR2I>& pts ) const
{
// in pts:
// A and B are points on the track ( pts[0] and pts[1] )
// C and E are points on the aViaPad ( pts[2] and pts[4] )
// D is the aViaPad centre ( pts[3] )
double Vpercent = aCurrParams->m_HeightRatio;
int td_height = aViaPad.m_Width * Vpercent;
// First, calculate a aVpercent equivalent to the td_height clamped by aTdMaxHeight
// We cannot use the initial aVpercent because it gives bad shape with points
// on aViaPad calculated for a clamped aViaPad size
if( aCurrParams->m_TdMaxHeight > 0 && aCurrParams->m_TdMaxHeight < td_height )
Vpercent *= (double)aCurrParams->m_TdMaxHeight / td_height;
int radius = aViaPad.m_Width / 2;
double minVpercent = double( aTrackHalfWidth ) / radius;
double weaken = (Vpercent - minVpercent) / ( 1 - minVpercent ) / radius;
double biasBC = 0.5 * SEG( pts[1], pts[2] ).Length();
double biasAE = 0.5 * SEG( pts[4], pts[0] ).Length();
VECTOR2I vecC = (VECTOR2I)pts[2] - aViaPad.m_Pos;
VECTOR2I tangentC = VECTOR2I( pts[2].x - vecC.y * biasBC * weaken,
pts[2].y + vecC.x * biasBC * weaken );
VECTOR2I vecE = (VECTOR2I)pts[4] - aViaPad.m_Pos;
VECTOR2I tangentE = VECTOR2I( pts[4].x + vecE.y * biasAE * weaken,
pts[4].y - vecE.x * biasAE * weaken );
VECTOR2I tangentB = VECTOR2I( pts[1].x - aTrackDir.x * biasBC, pts[1].y - aTrackDir.y * biasBC );
VECTOR2I tangentA = VECTOR2I( pts[0].x - aTrackDir.x * biasAE, pts[0].y - aTrackDir.y * biasAE );
std::vector<VECTOR2I> curve_pts;
curve_pts.reserve( aCurrParams->m_CurveSegCount );
BEZIER_POLY( pts[1], tangentB, tangentC, pts[2] ).GetPoly( curve_pts, 0,
aCurrParams->m_CurveSegCount );
for( VECTOR2I& corner: curve_pts )
aPoly.push_back( corner );
aPoly.push_back( pts[3] );
curve_pts.clear();
BEZIER_POLY( pts[4], tangentE, tangentA, pts[0] ).GetPoly( curve_pts, 0,
aCurrParams->m_CurveSegCount );
for( VECTOR2I& corner: curve_pts )
aPoly.push_back( corner );
}
/*
* Compute the curve part points for teardrops connected to a rectangular/polygonal shape
* The Bezier curve control points are not optimized for a special shape
*/
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void TEARDROP_MANAGER::computeCurvedForRectShape( TEARDROP_PARAMETERS* aCurrParams,
std::vector<VECTOR2I>& aPoly, int aTdHeight,
int aTrackHalfWidth, VIAPAD& aViaPad,
std::vector<VECTOR2I>& aPts ) const
{
// in aPts:
// A and B are points on the track ( pts[0] and pts[1] )
// C and E are points on the aViaPad ( pts[2] and pts[4] )
// D is the aViaPad centre ( pts[3] )
// side1 is( aPts[1], aPts[2] ); from track to via
VECTOR2I side1( aPts[2] - aPts[1] ); // vector from track to via
// side2 is ( aPts[4], aPts[0] ); from via to track
VECTOR2I side2( aPts[4] - aPts[0] ); // vector from track to via
std::vector<VECTOR2I> curve_pts;
curve_pts.reserve( aCurrParams->m_CurveSegCount );
// Note: This side is from track to via
VECTOR2I ctrl1 = ( aPts[1] + aPts[1] + aPts[2] ) / 3;
VECTOR2I ctrl2 = ( aPts[1] + aPts[2] + aPts[2] ) / 3;
// The control points must be moved toward the polygon inside, in order to give a curved shape
// The move vector is perpendicular to the vertex (side 1 or side 2), and its
// value is delta, depending on the sizes of via and track
int delta = ( aTdHeight / 2 - aTrackHalfWidth );
delta /= 4; // A scaling factor giving a fine shape, defined from tests.
// However for short sides, the value of delta must be reduced, depending
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// on the side length
// We use here a max delta value = side_length/8, defined from tests
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int side_length = side1.EuclideanNorm();
int delta_effective = std::min( delta, side_length/8 );
// The move vector depend on the quadrant: it must be always defined to create a
// curve with a direction toward the track
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EDA_ANGLE angle1( side1 );
int sign = std::abs( angle1 ) >= ANGLE_90 ? 1 : -1;
VECTOR2I bias( 0, sign * delta_effective );
// Does not works well with the current algo, due to an initial bug.
// but I (JPC) keep it here because probably it will gives a better shape
// if the algo is refined.
// RotatePoint( bias, angle1 );
ctrl1.x += bias.x;
ctrl1.y += bias.y;
ctrl2.x += bias.x;
ctrl2.y += bias.y;
BEZIER_POLY( aPts[1], ctrl1, ctrl2, aPts[2] ).GetPoly( curve_pts, 0,
aCurrParams->m_CurveSegCount );
for( VECTOR2I& corner: curve_pts )
aPoly.push_back( corner );
aPoly.push_back( aPts[3] );
// Note: This side is from via to track
curve_pts.clear();
ctrl1 = ( aPts[4] + aPts[4] + aPts[0] ) / 3;
ctrl2 = ( aPts[4] + aPts[0] + aPts[0] ) / 3;
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side_length = side2.EuclideanNorm();
delta_effective = std::min( delta, side_length/8 );
EDA_ANGLE angle2( side2 );
sign = std::abs( angle2 ) <= ANGLE_90 ? 1 : -1;
bias = VECTOR2I( 0, sign * delta_effective );
// Does not works well with the current algo
// RotatePoint( bias, angle2 );
ctrl1.x += bias.x;
ctrl1.y += bias.y;
ctrl2.x += bias.x;
ctrl2.y += bias.y;
BEZIER_POLY( aPts[4], ctrl1, ctrl2, aPts[0] ).GetPoly( curve_pts, 0,
aCurrParams->m_CurveSegCount );
for( VECTOR2I& corner: curve_pts )
aPoly.push_back( corner );
}
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bool TEARDROP_MANAGER::ComputePointsOnPadVia( TEARDROP_PARAMETERS* aCurrParams,
PCB_TRACK* aTrack,
VIAPAD& aViaPad,
std::vector<VECTOR2I>& aPts ) const
{
// Compute the 2 anchor points on pad/via of the teardrop shape
PAD* pad = ( aViaPad.m_Parent->Type() == PCB_PAD_T ) ? static_cast<PAD*>(aViaPad.m_Parent)
: nullptr;
SHAPE_POLY_SET c_buffer;
// aHeightRatio is the factor to calculate the aViaPad teardrop preferred height
// teardrop height = aViaPad size * aHeightRatio (aHeightRatio <= 1.0)
// For rectangular (and similar) shapes, the preferred_height is calculated from the min
// dim of the rectangle = aViaPad.m_Width
int preferred_height = aViaPad.m_Width * aCurrParams->m_HeightRatio;
// force_clip_shape = true to force the via/pad polygon to be clipped to follow
// constraints
// Clipping is also needed for rectangular shapes, because the teardrop shape is
// restricted to a polygonal area smaller than the pad area (the teardrop height
// use the smaller value of X and Y sizes).
bool force_clip_shape = aCurrParams->m_HeightRatio < 1.0;
// To find the anchor points on via/pad shape, we build the polygonal shape, and clip the polygon
// to the max size (preferred_height or m_TdMaxHeight) by a rectangle centered on the
// axis of the expected teardrop shape.
// (only reduce the size of polygonal shape does not give good anchor points)
if( aViaPad.m_IsRound )
{
TransformCircleToPolygon( c_buffer, aViaPad.m_Pos, aViaPad.m_Width/2 ,
ARC_LOW_DEF, ERROR_INSIDE, 16 );
}
else // Only PADS can have a not round shape
{
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wxCHECK( pad, false );
force_clip_shape = true;
preferred_height = aViaPad.m_Width * aCurrParams->m_HeightRatio;
pad->TransformShapeToPolygon( c_buffer, aTrack->GetLayer(), 0, ARC_LOW_DEF, ERROR_INSIDE );
}
// Clip the pad/via shape to match the m_TdMaxHeight constraint, and for
// not rounded pad, clip the shape at the aViaPad.m_Width, i.e. the value
// of the smallest value between size.x and size.y values.
if( force_clip_shape || ( aCurrParams->m_TdMaxHeight > 0
&& aCurrParams->m_TdMaxHeight < preferred_height ) )
{
int halfsize = std::min( aCurrParams->m_TdMaxHeight, preferred_height )/2;
// teardrop_axis is the line from anchor point on the track and the end point
// of the teardrop in the pad/via
// this is the teardrop_axis of the teardrop shape to build
VECTOR2I ref_on_track = ( aPts[0] + aPts[1] ) / 2;
VECTOR2I teardrop_axis( aPts[3] - ref_on_track );
EDA_ANGLE orient( teardrop_axis );
int len = teardrop_axis.EuclideanNorm();
// Build the constraint polygon: a rectangle with
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// length = dist between the point on track and the pad/via pos
// height = m_TdMaxHeight or aViaPad.m_Width
SHAPE_POLY_SET clipping_rect;
clipping_rect.NewOutline();
// Build a horizontal rect: it will be rotated later
clipping_rect.Append( 0, - halfsize );
clipping_rect.Append( 0, halfsize );
clipping_rect.Append( len, halfsize );
clipping_rect.Append( len, - halfsize );
clipping_rect.Rotate( -orient );
clipping_rect.Move( ref_on_track );
// Clip the shape to the max allowed teadrop area
c_buffer.BooleanIntersection( clipping_rect, SHAPE_POLY_SET::PM_FAST );
}
/* in aPts:
* A and B are points on the track ( aPts[0] and aPts[1] )
* C and E are points on the aViaPad ( aPts[2] and aPts[4] )
* D is midpoint behind the aViaPad centre ( aPts[3] )
*/
SHAPE_LINE_CHAIN& padpoly = c_buffer.Outline(0);
std::vector<VECTOR2I> points = padpoly.CPoints();
std::vector<VECTOR2I> initialPoints;
initialPoints.push_back( aPts[0] );
initialPoints.push_back( aPts[1] );
for( const VECTOR2I& pt: points )
initialPoints.emplace_back( pt.x, pt.y );
std::vector<VECTOR2I> hull;
BuildConvexHull( hull, initialPoints );
// Search for end points of segments starting at aPts[0] or aPts[1]
// In some cases, in convex hull, only one point (aPts[0] or aPts[1]) is still in list
VECTOR2I PointC;
VECTOR2I PointE;
int found_start = -1; // 2 points (one start and one end) should be found
int found_end = -1;
VECTOR2I start = aPts[0];
VECTOR2I pend = aPts[1];
for( unsigned ii = 0, jj = 0; jj < hull.size(); ii++, jj++ )
{
unsigned next = ii+ 1;
if( next >= hull.size() )
next = 0;
int prev = ii -1;
if( prev < 0 )
prev = hull.size()-1;
if( hull[ii] == start )
{
// the previous or the next point is candidate:
if( hull[next] != pend )
PointE = hull[next];
else
PointE = hull[prev];
found_start = ii;
}
if( hull[ii] == pend )
{
if( hull[next] != start )
PointC = hull[next];
else
PointC = hull[prev];
found_end = ii;
}
}
if( found_start < 0 ) // PointE was not initialized, because start point does not exit
{
int ii = found_end-1;
if( ii < 0 )
ii = hull.size()-1;
PointE = hull[ii];
}
if( found_end < 0 ) // PointC was not initialized, because end point does not exit
{
int ii = found_start-1;
if( ii < 0 )
ii = hull.size()-1;
PointC = hull[ii];
}
aPts[2] = PointC;
aPts[4] = PointE;
// Now we have to know if the choice aPts[2] = PointC is the best, or if
// aPts[2] = PointE is better.
// A criteria is to calculate the polygon area in these 2 cases, and choose the case
// that gives the bigger area, because the segments starting at PointC and PointE
// maximize their distance.
SHAPE_LINE_CHAIN dummy1( aPts, true );
double area1 = dummy1.Area();
std::swap( aPts[2], aPts[4] );
SHAPE_LINE_CHAIN dummy2( aPts, true );
double area2 = dummy2.Area();
if( area1 > area2 ) // The first choice (without swapping) is the better.
std::swap( aPts[2], aPts[4] );
return true;
}
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bool TEARDROP_MANAGER::findAnchorPointsOnTrack( TEARDROP_PARAMETERS* aCurrParams,
VECTOR2I& aStartPoint, VECTOR2I& aEndPoint,
PCB_TRACK*& aTrack, VIAPAD& aViaPad,
int* aEffectiveTeardropLen,
bool aFollowTracks,
TRACK_BUFFER& aTrackLookupList ) const
{
bool found = true;
VECTOR2I start = aTrack->GetStart();
VECTOR2I end = aTrack->GetEnd();
int radius = aViaPad.m_Width / 2;
// Requested length of the teardrop:
int targetLength = aViaPad.m_Width * aCurrParams->m_LengthRatio;
if( aCurrParams->m_TdMaxLen > 0 )
targetLength = std::min( aCurrParams->m_TdMaxLen, targetLength );
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int actualTdLen; // The actual teardrop length, limited by the available track length
// ensure that start is at the via/pad end
if( SEG( end, aViaPad.m_Pos ).Length() < radius )
{
std::swap( start, end );
}
SHAPE_POLY_SET shapebuffer;
if( aViaPad.m_IsRound )
{
TransformCircleToPolygon( shapebuffer, aViaPad.m_Pos, radius,
ARC_LOW_DEF, ERROR_INSIDE, 16 );
}
else
{
PAD* pad = static_cast<PAD*>( aViaPad.m_Parent );
pad->TransformShapeToPolygon( shapebuffer, aTrack->GetLayer(), 0,
ARC_LOW_DEF, ERROR_INSIDE );
}
SHAPE_LINE_CHAIN& outline = shapebuffer.Outline(0);
outline.SetClosed( true );
// Search the intersection point between the pad/via shape and the current track
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// This this the starting point to define the teardrop length
SHAPE_LINE_CHAIN::INTERSECTIONS pts;
int pt_count = outline.Intersect( SEG( start, end ), pts );
// Ensure a intersection point was found, otherwise we cannot built the teardrop
// using this track
if( pt_count < 1 )
return false;
VECTOR2I intersect = pts[0].p;
start.x = intersect.x;
start.y = intersect.y;
actualTdLen = std::min( targetLength, SEG( start, end ).Length() );
// If the first track is too short to allow a teardrop having the requested length
// explore the connected track(s)
if( actualTdLen < targetLength && aFollowTracks )
{
int consumed = 0;
while( actualTdLen+consumed < targetLength )
{
EDA_ITEM_FLAGS matchType;
PCB_TRACK* connected_track = findTouchingTrack( matchType, aTrack, end, aTrackLookupList );
if( connected_track == nullptr )
break;
// TODO: stop if angle between old and new segment is > 45 deg to avoid bad shape
consumed += actualTdLen;
actualTdLen = std::min( targetLength-consumed, int( connected_track->GetLength() ) );
aTrack = connected_track;
end = connected_track->GetEnd();
start = connected_track->GetStart();
if( matchType != STARTPOINT )
std::swap( start, end );
// If we do not want to explore more than one connected track, stop search here
break;
}
}
aStartPoint = start;
aEndPoint = end;
*aEffectiveTeardropLen = actualTdLen;
return found;
}
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bool TEARDROP_MANAGER::computeTeardropPolygonPoints( TEARDROP_PARAMETERS* aCurrParams,
std::vector<VECTOR2I>& aCorners,
PCB_TRACK* aTrack, VIAPAD& aViaPad,
bool aFollowTracks,
TRACK_BUFFER& aTrackLookupList ) const
{
VECTOR2I start, end; // Start and end points of the track anchor of the teardrop
// the start point is inside the teardrop shape
// the end point is outside.
int track_stub_len; // the dist between the start point and the anchor point
// on the track
// Note: aTrack can be modified if the initial track is too short
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if( !findAnchorPointsOnTrack( aCurrParams, start, end, aTrack, aViaPad, &track_stub_len,
aFollowTracks, aTrackLookupList ) )
return false;
// The start and end points must be different to calculate a valid polygon shape
if( start == end )
return false;
VECTOR2D vecT = NormalizeVector(end - start);
// find the 2 points on the track, sharp end of the teardrop
int track_halfwidth = aTrack->GetWidth() / 2;
VECTOR2I pointB = start + VECTOR2I( vecT.x * track_stub_len + vecT.y * track_halfwidth,
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vecT.y * track_stub_len - vecT.x * track_halfwidth );
VECTOR2I pointA = start + VECTOR2I( vecT.x * track_stub_len - vecT.y * track_halfwidth,
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vecT.y * track_stub_len + vecT.x * track_halfwidth );
// To build a polygonal valid shape pointA and point B must be outside the pad
// It can be inside with some pad shapes having very different X and X sizes
if( !aViaPad.m_IsRound )
{
PAD* pad = static_cast<PAD*>( aViaPad.m_Parent );
if( pad->HitTest( pointA ) )
return false;
if( pad->HitTest( pointB ) )
return false;
}
// Introduce a last point to cover the via centre to ensure it is seen as connected
VECTOR2I pointD = aViaPad.m_Pos;
// add a small offset in order to have the aViaPad.m_Pos reference point inside
// the teardrop area, just in case...
int offset = pcbIUScale.mmToIU( 0.001 );
pointD += VECTOR2I( int( -vecT.x*offset), int(-vecT.y*offset) );
VECTOR2I pointC, pointE; // Point on PADVIA outlines
std::vector<VECTOR2I> pts = {pointA, pointB, pointC, pointD, pointE};
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ComputePointsOnPadVia( aCurrParams, aTrack, aViaPad, pts );
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if( !aCurrParams->IsCurved() )
{
aCorners = pts;
return true;
}
// See if we can use curved teardrop shape
if( aViaPad.m_IsRound )
{
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computeCurvedForRoundShape( aCurrParams, aCorners, track_halfwidth, vecT, aViaPad, pts );
}
else
{
int td_height = aViaPad.m_Width * aCurrParams->m_HeightRatio;
if( aCurrParams->m_TdMaxHeight > 0 && aCurrParams->m_TdMaxHeight < td_height )
td_height = aCurrParams->m_TdMaxHeight;
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computeCurvedForRectShape( aCurrParams, aCorners, td_height, track_halfwidth,
aViaPad, pts );
}
return true;
}