932 lines
38 KiB
C++
932 lines
38 KiB
C++
/**********************************************/
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/* board_items_to_polygon_shape_transform.cpp */
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/**********************************************/
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/* Function to convert pads and tranck shapes to polygons
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* Used to fill zones areas
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*/
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#include <vector>
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#include "fctsys.h"
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#include "common.h"
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#include "pcbnew.h"
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#include "wxPcbStruct.h"
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#include "trigo.h"
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/* Exported functions */
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/** Function TransformRoundedEndsSegmentToPolygon
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* convert a segment with rounded ends to a polygon
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* Convert arcs to multiple straight lines
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* @param aCornerBuffer = a buffer to store the polygon
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* @param aStart = the segment start point coordinate
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* @param aEnd = the segment end point coordinate
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* @param aCircleToSegmentsCount = the number of segments to approximate a circle
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* @param aWidth = the segment width
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*/
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void TransformRoundedEndsSegmentToPolygon( std::vector <CPolyPt>& aCornerBuffer,
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wxPoint aStart, wxPoint aEnd,
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int aCircleToSegmentsCount,
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int aWidth );
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/** Function TransformArcToPolygon
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* Creates a polygon from an Arc
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* Convert arcs to multiple straight segments
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* @param aCornerBuffer = a buffer to store the polygon
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* @param aCentre = centre of the arc or circle
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* @param aStart = start point of the arc, or a point on the circle
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* @param aArcAngle = arc angle in 0.1 degrees. For a circle, aArcAngle = 3600
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* @param aCircleToSegmentsCount = the number of segments to approximate a circle
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* @param aWidth = width (thickness) of the line
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*/
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void TransformArcToPolygon( std::vector <CPolyPt>& aCornerBuffer,
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wxPoint aCentre, wxPoint aStart, int aArcAngle,
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int aCircleToSegmentsCount, int aWidth )
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{
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wxPoint arc_start, arc_end;
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int delta = 3600 / aCircleToSegmentsCount; // rot angle in 0.1 degree
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arc_end = arc_start = aStart;
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if( aArcAngle != 3600 )
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{
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RotatePoint( &arc_end, aCentre, -aArcAngle );
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}
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if( aArcAngle < 0 )
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{
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EXCHG( arc_start, arc_end );
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NEGATE( aArcAngle );
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}
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// Compute the ends of segments and creates poly
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wxPoint curr_end = arc_start;
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wxPoint curr_start = arc_start;
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for( int ii = delta; ii < aArcAngle; ii += delta )
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{
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curr_end = arc_start;
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RotatePoint( &curr_end, aCentre, -ii );
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TransformRoundedEndsSegmentToPolygon( aCornerBuffer,
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curr_start, curr_end, aCircleToSegmentsCount, aWidth );
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curr_start = curr_end;
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}
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if( curr_end != arc_end )
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TransformRoundedEndsSegmentToPolygon( aCornerBuffer,
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curr_end, arc_end, aCircleToSegmentsCount, aWidth );
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}
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/** Function TEXTE_PCB::TransformShapeWithClearanceToPolygon
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* Convert the track shape to a closed polygon
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* Used in filling zones calculations
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* Circles and arcs are approximated by segments
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* @param aCornerBuffer = a buffer to store the polygon
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* @param aClearanceValue = the clearance around the pad
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* @param aCircleToSegmentsCount = the number of segments to approximate a circle
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* @param aCorrectionFactor = the correction to apply to circles radius to keep
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* clearance when the circle is approximated by segment bigger or equal
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* to the real clearance value (usually near from 1.0)
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*/
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void TEXTE_PCB::TransformShapeWithClearanceToPolygon(
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std::vector <CPolyPt>& aCornerBuffer,
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int aClearanceValue,
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int aCircleToSegmentsCount,
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double aCorrectionFactor )
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{
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if( GetLength() == 0 )
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return;
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CPolyPt corners[4]; // Buffer of polygon corners
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EDA_Rect rect = GetTextBox( -1 );
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rect.Inflate( aClearanceValue );
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corners[0].x = rect.GetOrigin().x;
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corners[0].y = rect.GetOrigin().y;
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corners[1].y = corners[0].y;
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corners[1].x = rect.GetRight();
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corners[2].x = corners[1].x;
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corners[2].y = rect.GetBottom();
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corners[3].y = corners[2].y;
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corners[3].x = corners[0].x;
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for( int ii = 0; ii < 4; ii++ )
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{
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// Rotate polygon
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RotatePoint( &corners[ii].x, &corners[ii].y,
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m_Pos.x, m_Pos.y,
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m_Orient );
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aCornerBuffer.push_back( corners[ii] );
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}
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aCornerBuffer.back().end_contour = true;
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}
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/** Function DRAWSEGMENT::TransformShapeWithClearanceToPolygon
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* Convert the track shape to a closed polygon
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* Used in filling zones calculations
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* Circles and arcs are approximated by segments
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* @param aCornerBuffer = a buffer to store the polygon
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* @param aClearanceValue = the clearance around the pad
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* @param aCircleToSegmentsCount = the number of segments to approximate a circle
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* @param aCorrectionFactor = the correction to apply to circles radius to keep
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* clearance when the circle is approxiamted by segment bigger or equal
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* to the real clearance value (usually near from 1.0)
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*/
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void DRAWSEGMENT::TransformShapeWithClearanceToPolygon(
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std::vector <CPolyPt>& aCornerBuffer,
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int aClearanceValue,
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int aCircleToSegmentsCount,
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double aCorrectionFactor )
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{
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switch( m_Shape )
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{
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case S_CIRCLE:
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TransformArcToPolygon( aCornerBuffer, m_Start, // Circle centre
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m_End, 3600,
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aCircleToSegmentsCount,
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m_Width + (2 * aClearanceValue) );
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break;
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case S_ARC:
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TransformArcToPolygon( aCornerBuffer, m_Start,
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m_End, m_Angle,
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aCircleToSegmentsCount,
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m_Width + (2 * aClearanceValue) );
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break;
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default:
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TransformRoundedEndsSegmentToPolygon(
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aCornerBuffer, m_Start, m_End,
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aCircleToSegmentsCount, m_Width + (2 * aClearanceValue) );
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break;
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}
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}
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/** Function EDGE_MODULE::TransformShapeWithClearanceToPolygon
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* Convert the track shape to a closed polygon
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* Used in filling zones calculations
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* Circles and arcs are approximated by segments
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* @param aCornerBuffer = a buffer to store the polygon
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* @param aClearanceValue = the clearance around the pad
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* @param aCircleToSegmentsCount = the number of segments to approximate a circle
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* @param aCorrectionFactor = the correction to apply to circles radius to keep
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* clearance when the circle is approxiamted by segment bigger or equal
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* to the real clearance value (usually near from 1.0)
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*/
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void EDGE_MODULE::TransformShapeWithClearanceToPolygon(
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std::vector <CPolyPt>& aCornerBuffer,
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int aClearanceValue,
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int aCircleToSegmentsCount,
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double aCorrectionFactor )
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{
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switch( m_Shape )
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{
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case S_CIRCLE:
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TransformArcToPolygon( aCornerBuffer, m_Start, // Circle centre
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m_End, 3600,
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aCircleToSegmentsCount,
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m_Width + (2 * aClearanceValue) );
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break;
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case S_ARC:
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TransformArcToPolygon( aCornerBuffer, m_Start,
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m_End, m_Angle,
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aCircleToSegmentsCount,
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m_Width + (2 * aClearanceValue) );
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break;
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case S_SEGMENT:
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TransformRoundedEndsSegmentToPolygon(
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aCornerBuffer, m_Start, m_End,
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aCircleToSegmentsCount, m_Width + (2 * aClearanceValue) );
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break;
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default:
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break;
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}
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}
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/** Function TRACK::TransformShapeWithClearanceToPolygon
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* Convert the track shape to a closed polygon
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* Used in filling zones calculations
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* Circles (vias) and arcs (ends of tracks) are approximated by segments
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* @param aCornerBuffer = a buffer to store the polygon
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* @param aClearanceValue = the clearance around the pad
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* @param aCircleToSegmentsCount = the number of segments to approximate a circle
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* @param aCorrectionFactor = the correction to apply to circles radius to keep
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* clearance when the circle is approxiamted by segment bigger or equal
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* to the real clearance value (usually near from 1.0)
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*/
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void TRACK:: TransformShapeWithClearanceToPolygon( std:: vector < CPolyPt>& aCornerBuffer,
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int aClearanceValue,
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int aCircleToSegmentsCount,
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double aCorrectionFactor )
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{
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wxPoint corner_position;
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int ii, angle;
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int dx = (m_Width / 2) + aClearanceValue;
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int delta = 3600 / aCircleToSegmentsCount; // rot angle in 0.1 degree
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switch( Type() )
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{
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case TYPE_VIA:
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dx = (int) ( dx * aCorrectionFactor );
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for( ii = 0; ii < aCircleToSegmentsCount; ii++ )
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{
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corner_position = wxPoint( dx, 0 );
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RotatePoint( &corner_position.x, &corner_position.y,
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(1800 / aCircleToSegmentsCount) );
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angle = ii * delta;
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RotatePoint( &corner_position.x, &corner_position.y, angle );
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corner_position.x += m_Start.x;
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corner_position.y += m_Start.y;
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CPolyPt polypoint( corner_position.x, corner_position.y );
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aCornerBuffer.push_back( polypoint );
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}
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aCornerBuffer.back().end_contour = true;
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break;
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default:
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TransformRoundedEndsSegmentToPolygon(
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aCornerBuffer,
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m_Start, m_End,
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aCircleToSegmentsCount,
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m_Width + ( 2 * aClearanceValue) );
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break;
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}
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}
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/* Function TransformRoundedEndsSegmentToPolygon
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*/
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void TransformRoundedEndsSegmentToPolygon( std::vector <CPolyPt>& aCornerBuffer,
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wxPoint aStart, wxPoint aEnd,
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int aCircleToSegmentsCount,
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int aWidth )
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{
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int rayon = aWidth / 2;
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wxPoint endp = aEnd - aStart; // end point coordinate for the same segment starting at (0,0)
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wxPoint startp = aStart;
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wxPoint corner;
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int seg_len;
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CPolyPt polypoint;
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// normalize the position in order to have endp.x >= 0;
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if( endp.x < 0 )
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{
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endp = aStart - aEnd;
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startp = aEnd;
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}
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int delta_angle = ArcTangente( endp.y, endp.x ); // delta_angle is in 0.1 degrees
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seg_len = (int) sqrt( ( (double) endp.y * endp.y ) + ( (double) endp.x * endp.x ) );
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int delta = 3600 / aCircleToSegmentsCount; // rot angle in 0.1 degree
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// Compute the outlines of the segment, and creates a polygon
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corner = wxPoint( 0, rayon );
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RotatePoint( &corner, -delta_angle );
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corner += startp;
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polypoint.x = corner.x;
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polypoint.y = corner.y;
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aCornerBuffer.push_back( polypoint );
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corner = wxPoint( seg_len, rayon );
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RotatePoint( &corner, -delta_angle );
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corner += startp;
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polypoint.x = corner.x;
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polypoint.y = corner.y;
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aCornerBuffer.push_back( polypoint );
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// add right rounded end:
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for( int ii = delta; ii < 1800; ii += delta )
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{
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corner = wxPoint( 0, rayon );
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RotatePoint( &corner, ii );
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corner.x += seg_len;
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RotatePoint( &corner, -delta_angle );
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corner += startp;
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polypoint.x = corner.x;
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polypoint.y = corner.y;
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aCornerBuffer.push_back( polypoint );
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}
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corner = wxPoint( seg_len, -rayon );
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RotatePoint( &corner, -delta_angle );
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corner += startp;
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polypoint.x = corner.x;
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polypoint.y = corner.y;
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aCornerBuffer.push_back( polypoint );
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corner = wxPoint( 0, -rayon );
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RotatePoint( &corner, -delta_angle );
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corner += startp;
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polypoint.x = corner.x;
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polypoint.y = corner.y;
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aCornerBuffer.push_back( polypoint );
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// add left rounded end:
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for( int ii = delta; ii < 1800; ii += delta )
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{
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corner = wxPoint( 0, -rayon );
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RotatePoint( &corner, ii );
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RotatePoint( &corner, -delta_angle );
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corner += startp;
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polypoint.x = corner.x;
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polypoint.y = corner.y;
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aCornerBuffer.push_back( polypoint );
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}
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aCornerBuffer.back().end_contour = true;
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}
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/** function D_PAD::TransformShapeWithClearanceToPolygon
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* Convert the pad shape to a closed polygon
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* Used in filling zones calculations
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* Circles and arcs are approximated by segments
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* @param aCornerBuffer = a buffer to store the polygon
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* @param aClearanceValue = the clearance around the pad
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* @param aCircleToSegmentsCount = the number of segments to approximate a circle
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* @param aCorrectionFactor = the correction to apply to circles radius to keep
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* clearance when the circle is approxiamted by segment bigger or equal
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* to the real clearance value (usually near from 1.0)
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*/
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void D_PAD:: TransformShapeWithClearanceToPolygon( std:: vector < CPolyPt>& aCornerBuffer,
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int aClearanceValue,
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int aCircleToSegmentsCount,
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double aCorrectionFactor )
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{
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wxPoint corner_position;
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int ii, angle;
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int dx = (m_Size.x / 2) + aClearanceValue;
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int dy = (m_Size.y / 2) + aClearanceValue;
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int delta = 3600 / aCircleToSegmentsCount; // rot angle in 0.1 degree
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wxPoint PadShapePos = ReturnShapePos(); /* Note: for pad having a shape offset,
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* the pad position is NOT the shape position */
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wxSize psize = m_Size; /* pad size unsed in RECT and TRAPEZOIDAL pads
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* trapezoidal pads are considered as rect pad shape having they boudary box size
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*/
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switch( m_PadShape )
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{
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case PAD_CIRCLE:
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dx = (int) ( dx * aCorrectionFactor );
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for( ii = 0; ii < aCircleToSegmentsCount; ii++ )
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{
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corner_position = wxPoint( dx, 0 );
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RotatePoint( &corner_position, (1800 / aCircleToSegmentsCount) );
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// Half increment offset to get more space between
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angle = ii * delta;
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RotatePoint( &corner_position, angle );
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corner_position += PadShapePos;
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CPolyPt polypoint( corner_position.x, corner_position.y );
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aCornerBuffer.push_back( polypoint );
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}
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aCornerBuffer.back().end_contour = true;
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break;
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case PAD_OVAL:
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angle = m_Orient;
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if( dy > dx ) // Oval pad X/Y ratio for choosing translation axles
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{
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dy = (int) ( dy * aCorrectionFactor );
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int angle_pg; // Polygon angle
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wxPoint shape_offset = wxPoint( 0, dy - dx );
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RotatePoint( &shape_offset, angle ); // Rotating shape offset vector with component
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for( ii = 0; ii < aCircleToSegmentsCount / 2 + 1; ii++ ) // Half circle end cap...
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{
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corner_position = wxPoint( dx, 0 );
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// Coordinate translation +dx
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RotatePoint( &corner_position, (1800 / aCircleToSegmentsCount) );
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RotatePoint( &corner_position, angle );
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angle_pg = ii * delta;
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RotatePoint( &corner_position, angle_pg );
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corner_position += PadShapePos - shape_offset;
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CPolyPt polypoint( corner_position.x, corner_position.y );
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aCornerBuffer.push_back( polypoint );
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}
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for( ii = 0; ii < aCircleToSegmentsCount / 2 + 1; ii++ ) // Second half circle end cap...
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{
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corner_position = wxPoint( -dx, 0 );
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// Coordinate translation -dx
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RotatePoint( &corner_position, (1800 / aCircleToSegmentsCount) );
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RotatePoint( &corner_position, angle );
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angle_pg = ii * delta;
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RotatePoint( &corner_position, angle_pg );
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corner_position += PadShapePos + shape_offset;
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CPolyPt polypoint( corner_position.x, corner_position.y );
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aCornerBuffer.push_back( polypoint );
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}
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aCornerBuffer.back().end_contour = true;
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break;
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}
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else //if( dy <= dx )
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{
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dx = (int) ( dx * aCorrectionFactor );
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int angle_pg; // Polygon angle
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wxPoint shape_offset = wxPoint( (dy - dx), 0 );
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RotatePoint( &shape_offset, angle );
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for( ii = 0; ii < aCircleToSegmentsCount / 2 + 1; ii++ )
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{
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corner_position = wxPoint( 0, dy );
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RotatePoint( &corner_position, (1800 / aCircleToSegmentsCount) );
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RotatePoint( &corner_position, angle );
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angle_pg = ii * delta;
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RotatePoint( &corner_position, angle_pg );
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corner_position += PadShapePos - shape_offset;
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CPolyPt polypoint( corner_position.x, corner_position.y );
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aCornerBuffer.push_back( polypoint );
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}
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for( ii = 0; ii < aCircleToSegmentsCount / 2 + 1; ii++ )
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{
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corner_position = wxPoint( 0, -dy );
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RotatePoint( &corner_position, (1800 / aCircleToSegmentsCount) );
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RotatePoint( &corner_position, angle );
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angle_pg = ii * delta;
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RotatePoint( &corner_position, angle_pg );
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corner_position += PadShapePos + shape_offset;
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CPolyPt polypoint( corner_position.x, corner_position.y );
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aCornerBuffer.push_back( polypoint );
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}
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aCornerBuffer.back().end_contour = true;
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break;
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}
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default:
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case PAD_TRAPEZOID:
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psize.x += ABS( m_DeltaSize.y );
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psize.y += ABS( m_DeltaSize.x );
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// fall through
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case PAD_RECT: // Easy implementation for rectangular cutouts with rounded corners // Easy implementation for rectangular cutouts with rounded corners
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angle = m_Orient;
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int rounding_radius = (int) ( aClearanceValue * aCorrectionFactor ); // Corner rounding radius
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int angle_pg; // Polygon increment angle
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for( int i = 0; i < aCircleToSegmentsCount / 4 + 1; i++ )
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{
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corner_position = wxPoint( 0, -rounding_radius );
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RotatePoint( &corner_position, (1800 / aCircleToSegmentsCount) );
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// Start at half increment offset
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angle_pg = i * delta;
|
|
RotatePoint( &corner_position, angle_pg );
|
|
|
|
// Rounding vector rotation
|
|
corner_position -= psize / 2; // Rounding vector + Pad corner offset
|
|
RotatePoint( &corner_position, angle );
|
|
|
|
// Rotate according to module orientation
|
|
corner_position += PadShapePos; // Shift origin to position
|
|
CPolyPt polypoint( corner_position.x, corner_position.y );
|
|
aCornerBuffer.push_back( polypoint );
|
|
}
|
|
|
|
for( int i = 0; i < aCircleToSegmentsCount / 4 + 1; i++ )
|
|
{
|
|
corner_position = wxPoint( -rounding_radius, 0 );
|
|
RotatePoint( &corner_position, (1800 / aCircleToSegmentsCount) );
|
|
angle_pg = i * delta;
|
|
RotatePoint( &corner_position, angle_pg );
|
|
corner_position -= wxPoint( psize.x / 2, -psize.y / 2 );
|
|
RotatePoint( &corner_position, angle );
|
|
corner_position += PadShapePos;
|
|
CPolyPt polypoint( corner_position.x, corner_position.y );
|
|
aCornerBuffer.push_back( polypoint );
|
|
}
|
|
|
|
for( int i = 0;
|
|
i < aCircleToSegmentsCount / 4 + 1;
|
|
i++ )
|
|
{
|
|
corner_position = wxPoint( 0, rounding_radius );
|
|
RotatePoint( &corner_position, (1800 / aCircleToSegmentsCount) );
|
|
angle_pg = i * delta;
|
|
RotatePoint( &corner_position, angle_pg );
|
|
corner_position += psize / 2;
|
|
RotatePoint( &corner_position, angle );
|
|
corner_position += PadShapePos;
|
|
CPolyPt polypoint( corner_position.x, corner_position.y );
|
|
aCornerBuffer.push_back( polypoint );
|
|
}
|
|
|
|
for( int i = 0; i < aCircleToSegmentsCount / 4 + 1; i++ )
|
|
{
|
|
corner_position = wxPoint( rounding_radius, 0 );
|
|
RotatePoint( &corner_position, (1800 / aCircleToSegmentsCount) );
|
|
angle_pg = i * delta;
|
|
RotatePoint( &corner_position, angle_pg );
|
|
corner_position -= wxPoint( -psize.x / 2, psize.y / 2 );
|
|
RotatePoint( &corner_position, angle );
|
|
corner_position += PadShapePos;
|
|
CPolyPt polypoint( corner_position.x, corner_position.y );
|
|
aCornerBuffer.push_back( polypoint );
|
|
}
|
|
|
|
aCornerBuffer.back().end_contour = true;
|
|
break;
|
|
}
|
|
}
|
|
|
|
|
|
/** function CreateThermalReliefPadPolygon
|
|
* Add holes around a pad to create a thermal relief
|
|
* copper thickness is min (dx/2, aCopperWitdh) or min (dy/2, aCopperWitdh)
|
|
* @param aCornerBuffer = a buffer to store the polygon
|
|
* @param aPad = the current pad used to create the thermal shape
|
|
* @param aThermalGap = gap in thermal shape
|
|
* @param aMinThicknessValue = min copper thickness allowed
|
|
* @param aCircleToSegmentsCount = the number of segments to approximate a circle
|
|
* @param aCorrectionFactor = the correction to apply to circles radius to keep
|
|
* @param aThermalRot = for rond pads the rotation of thermal stubs (450 usually for 45 deg.)
|
|
*/
|
|
|
|
/* thermal reliefs are created as 4 polygons.
|
|
* each corner of a polygon if calculated for a pad at position 0, 0, orient 0,
|
|
* and then moved and rotated acroding to the pad position and orientation
|
|
*/
|
|
|
|
/* WARNING:
|
|
* When Kbool calculates the filled areas :
|
|
* i.e when substracting holes (thermal shapes) to the full zone area
|
|
* under certains circumstances kboll drop some holes.
|
|
* These circumstances are:
|
|
* some identical holes (same thermal shape and size) are *exactly* on the same vertical line
|
|
* And
|
|
* nothing else between holes
|
|
* And
|
|
* angles less than 90 deg between 2 consecutive lines in hole outline (sometime occurs without this condition)
|
|
* And
|
|
* a hole above the identical holes
|
|
*
|
|
* In fact, it is easy to find these conditions in pad arrays.
|
|
* So to avoid this, the workaround is do not use holes outlines that include
|
|
* angles less than 90 deg between 2 consecutive lines
|
|
* this is made in round and oblong thermal reliefs
|
|
*
|
|
* Note 1: polygons are drawm using outlines witk a thickness = aMinThicknessValue
|
|
* so shapes must keep in account this outline thickness
|
|
*
|
|
* Note 2:
|
|
* Trapezoidal pads are not considered here because they are very special case
|
|
* and are used in microwave applications and they *DO NOT* have a thermal relief that change the shape
|
|
* by creating stubs and destroy their properties.
|
|
*/
|
|
void CreateThermalReliefPadPolygon( std::vector<CPolyPt>& aCornerBuffer,
|
|
D_PAD& aPad,
|
|
int aThermalGap,
|
|
int aCopperThickness,
|
|
int aMinThicknessValue,
|
|
int aCircleToSegmentsCount,
|
|
double aCorrectionFactor,
|
|
int aThermalRot )
|
|
{
|
|
wxPoint corner, corner_end;
|
|
wxPoint PadShapePos = aPad.ReturnShapePos(); /* Note: for pad having a shape offset,
|
|
* the pad position is NOT the shape position */
|
|
wxSize copper_thickness;
|
|
int dx = aPad.m_Size.x / 2;
|
|
int dy = aPad.m_Size.y / 2;
|
|
|
|
int delta = 3600 / aCircleToSegmentsCount; // rot angle in 0.1 degree
|
|
|
|
/* Keep in account the polygon outline thickness
|
|
* aThermalGap must be increased by aMinThicknessValue/2 because drawing external outline
|
|
* with a thickness of aMinThicknessValue will reduce gap by aMinThicknessValue/2
|
|
*/
|
|
aThermalGap += aMinThicknessValue / 2;
|
|
|
|
/* Keep in account the polygon outline thickness
|
|
* copper_thickness must be decreased by aMinThicknessValue because drawing outlines
|
|
* with a thickness of aMinThicknessValue will increase real thickness by aMinThicknessValue
|
|
*/
|
|
aCopperThickness -= aMinThicknessValue;
|
|
if( aCopperThickness < 0 )
|
|
aCopperThickness = 0;
|
|
|
|
copper_thickness.x = min( dx, aCopperThickness );
|
|
copper_thickness.y = min( dy, aCopperThickness );
|
|
|
|
switch( aPad.m_PadShape )
|
|
{
|
|
case PAD_CIRCLE: // Add 4 similar holes
|
|
{
|
|
/* we create 4 copper holes and put them in position 1, 2, 3 and 4
|
|
* here is the area of the rectangular pad + its thermal gap
|
|
* the 4 copper holes remove the copper in order to create the thermal gap
|
|
* 4 ------ 1
|
|
* | |
|
|
* | |
|
|
* | |
|
|
* | |
|
|
* 3 ------ 2
|
|
* holes 2, 3, 4 are the same as hole 1, rotated 90, 180, 270 deg
|
|
*/
|
|
|
|
// Build the hole pattern, for the hole in the X >0, Y > 0 plane:
|
|
// The pattern roughtly is a 90 deg arc pie
|
|
std::vector <wxPoint> corners_buffer;
|
|
|
|
// Radius of outer arcs of the shape:
|
|
int outer_radius = dx + aThermalGap; // The radius of the outer arc is pad radius + aThermalGap
|
|
|
|
// Crosspoint of thermal spoke sides, the first point of polygon buffer
|
|
corners_buffer.push_back( wxPoint( copper_thickness.x / 2, copper_thickness.y / 2 ) );
|
|
|
|
// Add an intermediate point on spoke sides, to allow a > 90 deg angle between side and first seg of arc approx
|
|
corner.x = copper_thickness.x / 2;
|
|
int y = outer_radius - (aThermalGap / 4);
|
|
corner.y = (int) sqrt( ( ( (double) y * y ) - (double) corner.x * corner.x ) );
|
|
if( aThermalRot != 0 )
|
|
corners_buffer.push_back( corner );
|
|
|
|
// calculate the starting point of the outter arc
|
|
corner.x = copper_thickness.x / 2;
|
|
double dtmp =
|
|
sqrt( ( (double) outer_radius * outer_radius ) - ( (double) corner.x * corner.x ) );
|
|
corner.y = (int) dtmp;
|
|
RotatePoint( &corner, 90 );
|
|
|
|
// calculate the ending point of the outter arc
|
|
corner_end.x = corner.y;
|
|
corner_end.y = corner.x;
|
|
|
|
// calculate intermediate points (y coordinate from corner.y to corner_end.y
|
|
while( (corner.y > corner_end.y) && (corner.x < corner_end.x) )
|
|
{
|
|
corners_buffer.push_back( corner );
|
|
RotatePoint( &corner, delta );
|
|
}
|
|
|
|
corners_buffer.push_back( corner_end );
|
|
|
|
/* add an intermediate point, to avoid angles < 90 deg between last arc approx line and radius line
|
|
*/
|
|
corner.x = corners_buffer[1].y;
|
|
corner.y = corners_buffer[1].x;
|
|
corners_buffer.push_back( corner );
|
|
|
|
// Now, add the 4 holes ( each is the pattern, rotated by 0, 90, 180 and 270 deg
|
|
// WARNING: problems with kbool if angle = 0 (in fact when angle < 200):
|
|
// bad filled polygon on some cases, when pads are on a same vertical line
|
|
// this seems a bug in kbool polygon (exists in 2.0 kbool version)
|
|
// aThermalRot = 450 (45.0 degrees orientation) seems work fine.
|
|
// aThermalRot = 0 with thermal shapes without angle < 90 deg has problems in rare circumstances
|
|
// Note: with the 2 step build ( thermal shapes added after areas are built), 0 seems work
|
|
int angle_pad = aPad.m_Orient; // Pad orientation
|
|
int th_angle = aThermalRot;
|
|
for( unsigned ihole = 0; ihole < 4; ihole++ )
|
|
{
|
|
for( unsigned ii = 0; ii < corners_buffer.size(); ii++ )
|
|
{
|
|
corner = corners_buffer[ii];
|
|
RotatePoint( &corner, th_angle + angle_pad ); // Rotate by segment angle and pad orientation
|
|
corner += PadShapePos;
|
|
aCornerBuffer.push_back( CPolyPt( corner.x, corner.y ) );
|
|
}
|
|
|
|
aCornerBuffer.back().end_contour = true;
|
|
th_angle += 900; // Note: th_angle in in 0.1 deg.
|
|
}
|
|
}
|
|
break;
|
|
|
|
case PAD_OVAL:
|
|
{
|
|
// Oval pad support along the lines of round and rectangular pads
|
|
std::vector <wxPoint> corners_buffer; // Polygon buffer as vector
|
|
|
|
int dx = (aPad.m_Size.x / 2) + aThermalGap; // Cutout radius x
|
|
int dy = (aPad.m_Size.y / 2) + aThermalGap; // Cutout radius y
|
|
|
|
wxPoint shape_offset;
|
|
|
|
// We want to calculate an oval shape with dx > dy.
|
|
// if this is not the case, exchange dx and dy, and rotate the shape 90 deg.
|
|
int supp_angle = 0;
|
|
if( dx < dy )
|
|
{
|
|
EXCHG( dx, dy );
|
|
supp_angle = 900;
|
|
EXCHG( copper_thickness.x, copper_thickness.y );
|
|
}
|
|
int deltasize = dx - dy; // = distance between shape position and the 2 demi-circle ends centre
|
|
// here we have dx > dy
|
|
// Radius of outer arcs of the shape:
|
|
int outer_radius = dy; // The radius of the outer arc is radius end + aThermalGap
|
|
|
|
// Some coordinate fiddling, depending on the shape offset direction
|
|
shape_offset = wxPoint( deltasize, 0 );
|
|
|
|
// Crosspoint of thermal spoke sides, the first point of polygon buffer
|
|
corners_buffer.push_back( wxPoint( copper_thickness.x / 2, copper_thickness.y / 2 ) );
|
|
|
|
// Arc start point calculation, the intersecting point of cutout arc and thermal spoke edge
|
|
if( copper_thickness.x > deltasize ) // If copper thickness is more than shape offset, we need to calculate arc intercept point.
|
|
{
|
|
corner.x = copper_thickness.x / 2;
|
|
corner.y =
|
|
(int) sqrt( ( (double) outer_radius * outer_radius ) -
|
|
( (double) ( corner.x - delta ) * ( corner.x - deltasize ) ) );
|
|
corner.x -= deltasize;
|
|
|
|
/* creates an intermediate point, to have a > 90 deg angle
|
|
* between the side and the first segment of arc approximation
|
|
*/
|
|
wxPoint intpoint = corner;
|
|
intpoint.y -= aThermalGap / 4;
|
|
corners_buffer.push_back( intpoint + shape_offset );
|
|
RotatePoint( &corner, 90 );
|
|
}
|
|
else
|
|
{
|
|
corner.x = copper_thickness.x / 2;
|
|
corner.y = outer_radius;
|
|
corners_buffer.push_back( corner );
|
|
corner.x = ( deltasize - copper_thickness.x ) / 2;
|
|
}
|
|
|
|
// Add an intermediate point on spoke sides, to allow a > 90 deg angle between side and first seg of arc approx
|
|
wxPoint last_corner;
|
|
last_corner.y = copper_thickness.y / 2;
|
|
int px = outer_radius - (aThermalGap / 4);
|
|
last_corner.x =
|
|
(int) sqrt( ( ( (double) px * px ) - (double) last_corner.y * last_corner.y ) );
|
|
|
|
// Arc stop point calculation, the intersecting point of cutout arc and thermal spoke edge
|
|
corner_end.y = copper_thickness.y / 2;
|
|
corner_end.x =
|
|
(int) sqrt( ( (double) outer_radius *
|
|
outer_radius ) - ( (double) corner_end.y * corner_end.y ) );
|
|
RotatePoint( &corner_end, -90 );
|
|
|
|
// calculate intermediate arc points till limit is reached
|
|
while( (corner.y > corner_end.y) && (corner.x < corner_end.x) )
|
|
{
|
|
corners_buffer.push_back( corner + shape_offset );
|
|
RotatePoint( &corner, delta );
|
|
}
|
|
|
|
//corners_buffer.push_back(corner + shape_offset); // TODO: about one mil geometry error forms somewhere.
|
|
corners_buffer.push_back( corner_end + shape_offset );
|
|
corners_buffer.push_back( last_corner + shape_offset ); // Enabling the line above shows intersection point.
|
|
|
|
/* Create 2 holes, rotated by pad rotation.
|
|
*/
|
|
int angle = aPad.m_Orient + supp_angle;
|
|
for( int irect = 0; irect < 2; irect++ )
|
|
{
|
|
for( unsigned ic = 0; ic < corners_buffer.size(); ic++ )
|
|
{
|
|
wxPoint cpos = corners_buffer[ic];
|
|
RotatePoint( &cpos, angle );
|
|
cpos += PadShapePos;
|
|
aCornerBuffer.push_back( CPolyPt( cpos.x, cpos.y ) );
|
|
}
|
|
|
|
aCornerBuffer.back().end_contour = true;;
|
|
angle += 1800; // this is calculate hole 3
|
|
if( angle >= 3600 )
|
|
angle -= 3600;
|
|
}
|
|
|
|
// Create holes, that are the mirrored from the previous holes
|
|
for( unsigned ic = 0; ic < corners_buffer.size(); ic++ )
|
|
{
|
|
wxPoint swap = corners_buffer[ic];
|
|
swap.x = -swap.x;
|
|
corners_buffer[ic] = swap;
|
|
}
|
|
|
|
// Now add corner 4 and 2 (2 is the corner 4 rotated by 180 deg
|
|
angle = aPad.m_Orient + supp_angle;
|
|
for( int irect = 0; irect < 2; irect++ )
|
|
{
|
|
for( unsigned ic = 0; ic < corners_buffer.size(); ic++ )
|
|
{
|
|
wxPoint cpos = corners_buffer[ic];
|
|
RotatePoint( &cpos, angle );
|
|
cpos += PadShapePos;
|
|
aCornerBuffer.push_back( CPolyPt( cpos.x, cpos.y ) );
|
|
}
|
|
|
|
aCornerBuffer.back().end_contour = true;
|
|
angle += 1800;
|
|
if( angle >= 3600 )
|
|
angle -= 3600;
|
|
}
|
|
}
|
|
break;
|
|
|
|
case PAD_RECT: // draw 4 Holes
|
|
{
|
|
/* we create 4 copper holes and put them in position 1, 2, 3 and 4
|
|
* here is the area of the rectangular pad + its thermal gap
|
|
* the 4 copper holes remove the copper in order to create the thermal gap
|
|
* 4 ------ 1
|
|
* | |
|
|
* | |
|
|
* | |
|
|
* | |
|
|
* 3 ------ 2
|
|
* hole 3 is the same as hole 1, rotated 180 deg
|
|
* hole 4 is the same as hole 2, rotated 180 deg and is the same as hole 1, mirrored
|
|
*/
|
|
|
|
// First, create a rectangular hole for position 1 :
|
|
// 2 ------- 3
|
|
// | |
|
|
// | |
|
|
// | |
|
|
// 1 -------4
|
|
|
|
// Modified rectangles with one corner rounded. TODO: merging with oval thermals and possibly round too.
|
|
|
|
std::vector <wxPoint> corners_buffer; // Polygon buffer as vector
|
|
|
|
int dx = (aPad.m_Size.x / 2) + aThermalGap; // Cutout radius x
|
|
int dy = (aPad.m_Size.y / 2) + aThermalGap; // Cutout radius y
|
|
|
|
// The first point of polygon buffer is left lower corner, second the crosspoint of thermal spoke sides,
|
|
// the third is upper right corner and the rest are rounding vertices going anticlockwise. Note the inveted Y-axis in CG.
|
|
corners_buffer.push_back( wxPoint( -dx, -(aThermalGap / 4 + copper_thickness.y / 2) ) ); // Adds small miters to zone
|
|
corners_buffer.push_back( wxPoint( -(dx - aThermalGap / 4), -copper_thickness.y / 2 ) ); // fill and spoke corner
|
|
corners_buffer.push_back( wxPoint( -copper_thickness.x / 2, -copper_thickness.y / 2 ) );
|
|
corners_buffer.push_back( wxPoint( -copper_thickness.x / 2, -(dy - aThermalGap / 4) ) );
|
|
corners_buffer.push_back( wxPoint( -(aThermalGap / 4 + copper_thickness.x / 2), -dy ) );
|
|
|
|
int angle = aPad.m_Orient;
|
|
int rounding_radius = (int) ( aThermalGap * aCorrectionFactor ); // Corner rounding radius
|
|
int angle_pg; // Polygon increment angle
|
|
|
|
for( int i = 0; i < aCircleToSegmentsCount / 4 + 1; i++ )
|
|
{
|
|
wxPoint corner_position = wxPoint( 0, -rounding_radius );
|
|
RotatePoint( &corner_position, 1800 / aCircleToSegmentsCount ); // Start at half increment offset
|
|
angle_pg = i * delta;
|
|
RotatePoint( &corner_position, angle_pg ); // Rounding vector rotation
|
|
corner_position -= aPad.m_Size / 2; // Rounding vector + Pad corner offset
|
|
corners_buffer.push_back( wxPoint( corner_position.x, corner_position.y ) );
|
|
}
|
|
|
|
for( int irect = 0; irect < 2; irect++ )
|
|
{
|
|
for( unsigned ic = 0; ic < corners_buffer.size(); ic++ )
|
|
{
|
|
wxPoint cpos = corners_buffer[ic];
|
|
RotatePoint( &cpos, angle ); // Rotate according to module orientation
|
|
cpos += PadShapePos; // Shift origin to position
|
|
aCornerBuffer.push_back( CPolyPt( cpos.x, cpos.y ) );
|
|
}
|
|
|
|
aCornerBuffer.back().end_contour = true;
|
|
angle += 1800; // this is calculate hole 3
|
|
if( angle >= 3600 )
|
|
angle -= 3600;
|
|
}
|
|
|
|
// Create holes, that are the mirrored from the previous holes
|
|
for( unsigned ic = 0; ic < corners_buffer.size(); ic++ )
|
|
{
|
|
wxPoint swap = corners_buffer[ic];
|
|
swap.x = -swap.x;
|
|
corners_buffer[ic] = swap;
|
|
}
|
|
|
|
// Now add corner 4 and 2 (2 is the corner 4 rotated by 180 deg
|
|
for( int irect = 0; irect < 2; irect++ )
|
|
{
|
|
for( unsigned ic = 0; ic < corners_buffer.size(); ic++ )
|
|
{
|
|
wxPoint cpos = corners_buffer[ic];
|
|
RotatePoint( &cpos, angle );
|
|
cpos += PadShapePos;
|
|
aCornerBuffer.push_back( CPolyPt( cpos.x, cpos.y ) );
|
|
}
|
|
|
|
aCornerBuffer.back().end_contour = true;
|
|
angle += 1800;
|
|
if( angle >= 3600 )
|
|
angle -= 3600;
|
|
}
|
|
|
|
break;
|
|
}
|
|
}
|
|
}
|