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kicad/eeschema/lib_arc.cpp

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/*
* This program source code file is part of KiCad, a free EDA CAD application.
*
* Copyright (C) 2017 Jean-Pierre Charras, jp.charras at wanadoo.fr
* Copyright (C) 2004-2020 KiCad Developers, see AUTHORS.txt for contributors.
* Copyright (C) 2019 CERN
*
* 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
*/
#include <sch_draw_panel.h>
#include <plotter.h>
#include <trigo.h>
#include <base_units.h>
#include <widgets/msgpanel.h>
#include <bitmaps.h>
#include <math/util.h> // for KiROUND
#include <eda_draw_frame.h>
#include <general.h>
#include <lib_arc.h>
#include <transform.h>
#include <settings/color_settings.h>
#include <status_popup.h>
// Helper function
static inline wxPoint twoPointVector( const wxPoint &startPoint, const wxPoint &endPoint )
{
return endPoint - startPoint;
}
LIB_ARC::LIB_ARC( LIB_PART* aParent ) : LIB_ITEM( LIB_ARC_T, aParent )
{
m_Radius = 0;
m_t1 = 0;
m_t2 = 0;
m_Width = 0;
m_Fill = FILL_TYPE::NO_FILL;
m_isFillable = true;
m_editState = 0;
}
bool LIB_ARC::HitTest( const wxPoint& aRefPoint, int aAccuracy ) const
{
int mindist = std::max( aAccuracy + GetPenWidth() / 2,
Mils2iu( MINIMUM_SELECTION_DISTANCE ) );
wxPoint relativePosition = aRefPoint;
relativePosition.y = -relativePosition.y; // reverse Y axis
int distance = KiROUND( GetLineLength( m_Pos, relativePosition ) );
if( abs( distance - m_Radius ) > mindist )
return false;
// We are on the circle, ensure we are only on the arc, i.e. between
// m_ArcStart and m_ArcEnd
wxPoint startEndVector = twoPointVector( m_ArcStart, m_ArcEnd );
wxPoint startRelativePositionVector = twoPointVector( m_ArcStart, relativePosition );
wxPoint centerStartVector = twoPointVector( m_Pos, m_ArcStart );
wxPoint centerEndVector = twoPointVector( m_Pos, m_ArcEnd );
wxPoint centerRelativePositionVector = twoPointVector( m_Pos, relativePosition );
// Compute the cross product to check if the point is in the sector
double crossProductStart = CrossProduct( centerStartVector, centerRelativePositionVector );
double crossProductEnd = CrossProduct( centerEndVector, centerRelativePositionVector );
// The cross products need to be exchanged, depending on which side the center point
// relative to the start point to end point vector lies
if( CrossProduct( startEndVector, startRelativePositionVector ) < 0 )
{
std::swap( crossProductStart, crossProductEnd );
}
// When the cross products have a different sign, the point lies in sector
// also check, if the reference is near start or end point
return HitTestPoints( m_ArcStart, relativePosition, MINIMUM_SELECTION_DISTANCE ) ||
HitTestPoints( m_ArcEnd, relativePosition, MINIMUM_SELECTION_DISTANCE ) ||
( crossProductStart <= 0 && crossProductEnd >= 0 );
}
bool LIB_ARC::HitTest( const EDA_RECT& aRect, bool aContained, int aAccuracy ) const
{
if( m_flags & (STRUCT_DELETED | SKIP_STRUCT ) )
return false;
wxPoint center = DefaultTransform.TransformCoordinate( GetPosition() );
int radius = GetRadius();
int lineWidth = GetWidth();
EDA_RECT sel = aRect ;
if ( aAccuracy )
sel.Inflate( aAccuracy );
if( aContained )
return sel.Contains( GetBoundingBox() );
EDA_RECT arcRect = GetBoundingBox().Common( sel );
/* All following tests must pass:
* 1. Rectangle must intersect arc BoundingBox
* 2. Rectangle must cross the outside of the arc
*/
return arcRect.Intersects( sel ) && arcRect.IntersectsCircleEdge( center, radius, lineWidth );
}
EDA_ITEM* LIB_ARC::Clone() const
{
return new LIB_ARC( *this );
}
int LIB_ARC::compare( const LIB_ITEM& aOther, LIB_ITEM::COMPARE_FLAGS aCompareFlags ) const
{
wxASSERT( aOther.Type() == LIB_ARC_T );
int retv = LIB_ITEM::compare( aOther );
if( retv )
return retv;
const LIB_ARC* tmp = ( LIB_ARC* ) &aOther;
if( m_Pos.x != tmp->m_Pos.x )
return m_Pos.x - tmp->m_Pos.x;
if( m_Pos.y != tmp->m_Pos.y )
return m_Pos.y - tmp->m_Pos.y;
if( m_t1 != tmp->m_t1 )
return m_t1 - tmp->m_t1;
if( m_t2 != tmp->m_t2 )
return m_t2 - tmp->m_t2;
return 0;
}
void LIB_ARC::Offset( const wxPoint& aOffset )
{
m_Pos += aOffset;
m_ArcStart += aOffset;
m_ArcEnd += aOffset;
}
void LIB_ARC::MoveTo( const wxPoint& aPosition )
{
wxPoint offset = aPosition - m_Pos;
m_Pos = aPosition;
m_ArcStart += offset;
m_ArcEnd += offset;
}
void LIB_ARC::MirrorHorizontal( const wxPoint& aCenter )
{
m_Pos.x -= aCenter.x;
m_Pos.x *= -1;
m_Pos.x += aCenter.x;
m_ArcStart.x -= aCenter.x;
m_ArcStart.x *= -1;
m_ArcStart.x += aCenter.x;
m_ArcEnd.x -= aCenter.x;
m_ArcEnd.x *= -1;
m_ArcEnd.x += aCenter.x;
std::swap( m_ArcStart, m_ArcEnd );
std::swap( m_t1, m_t2 );
m_t1 = 1800 - m_t1;
m_t2 = 1800 - m_t2;
if( m_t1 > 3600 || m_t2 > 3600 )
{
m_t1 -= 3600;
m_t2 -= 3600;
}
else if( m_t1 < -3600 || m_t2 < -3600 )
{
m_t1 += 3600;
m_t2 += 3600;
}
}
void LIB_ARC::MirrorVertical( const wxPoint& aCenter )
{
m_Pos.y -= aCenter.y;
m_Pos.y *= -1;
m_Pos.y += aCenter.y;
m_ArcStart.y -= aCenter.y;
m_ArcStart.y *= -1;
m_ArcStart.y += aCenter.y;
m_ArcEnd.y -= aCenter.y;
m_ArcEnd.y *= -1;
m_ArcEnd.y += aCenter.y;
std::swap( m_ArcStart, m_ArcEnd );
std::swap( m_t1, m_t2 );
m_t1 = - m_t1;
m_t2 = - m_t2;
if( m_t1 > 3600 || m_t2 > 3600 )
{
m_t1 -= 3600;
m_t2 -= 3600;
}
else if( m_t1 < -3600 || m_t2 < -3600 )
{
m_t1 += 3600;
m_t2 += 3600;
}
}
void LIB_ARC::Rotate( const wxPoint& aCenter, bool aRotateCCW )
{
int rot_angle = aRotateCCW ? -900 : 900;
RotatePoint( &m_Pos, aCenter, rot_angle );
RotatePoint( &m_ArcStart, aCenter, rot_angle );
RotatePoint( &m_ArcEnd, aCenter, rot_angle );
m_t1 -= rot_angle;
m_t2 -= rot_angle;
if( m_t1 > 3600 || m_t2 > 3600 )
{
m_t1 -= 3600;
m_t2 -= 3600;
}
else if( m_t1 < -3600 || m_t2 < -3600 )
{
m_t1 += 3600;
m_t2 += 3600;
}
}
void LIB_ARC::Plot( PLOTTER* aPlotter, const wxPoint& aOffset, bool aFill,
const TRANSFORM& aTransform )
{
wxASSERT( aPlotter != NULL );
int t1 = m_t1;
int t2 = m_t2;
wxPoint pos = aTransform.TransformCoordinate( m_Pos ) + aOffset;
aTransform.MapAngles( &t1, &t2 );
if( aFill && m_Fill == FILL_TYPE::FILLED_WITH_BG_BODYCOLOR )
{
aPlotter->SetColor( aPlotter->RenderSettings()->GetLayerColor( LAYER_DEVICE_BACKGROUND ) );
aPlotter->Arc( pos, -t2, -t1, m_Radius, FILL_TYPE::FILLED_WITH_BG_BODYCOLOR, 0 );
}
bool already_filled = m_Fill == FILL_TYPE::FILLED_WITH_BG_BODYCOLOR;
int pen_size = GetPenWidth();
if( !already_filled || pen_size > 0 )
{
pen_size = std::max( pen_size, aPlotter->RenderSettings()->GetMinPenWidth() );
aPlotter->SetColor( aPlotter->RenderSettings()->GetLayerColor( LAYER_DEVICE ) );
aPlotter->Arc(
pos, -t2, -t1, m_Radius, already_filled ? FILL_TYPE::NO_FILL : m_Fill, pen_size );
}
}
int LIB_ARC::GetPenWidth() const
{
// Historically 0 meant "default width" and negative numbers meant "don't stroke".
if( m_Width < 0 && GetFillMode() != FILL_TYPE::NO_FILL )
return 0;
else
return std::max( m_Width, 1 );
}
void LIB_ARC::print( RENDER_SETTINGS* aSettings, const wxPoint& aOffset, void* aData,
const TRANSFORM& aTransform )
{
bool forceNoFill = static_cast<bool>( aData );
int penWidth = GetPenWidth();
if( forceNoFill && m_Fill != FILL_TYPE::NO_FILL && penWidth == 0 )
return;
wxDC* DC = aSettings->GetPrintDC();
wxPoint pos1, pos2, posc;
COLOR4D color = aSettings->GetLayerColor( LAYER_DEVICE );
pos1 = aTransform.TransformCoordinate( m_ArcEnd ) + aOffset;
pos2 = aTransform.TransformCoordinate( m_ArcStart ) + aOffset;
posc = aTransform.TransformCoordinate( m_Pos ) + aOffset;
int pt1 = m_t1;
int pt2 = m_t2;
bool swap = aTransform.MapAngles( &pt1, &pt2 );
if( swap )
{
std::swap( pos1.x, pos2.x );
std::swap( pos1.y, pos2.y );
}
if( forceNoFill || m_Fill == FILL_TYPE::NO_FILL )
{
penWidth = std::max( penWidth, aSettings->GetDefaultPenWidth() );
GRArc1( nullptr, DC, pos1.x, pos1.y, pos2.x, pos2.y, posc.x, posc.y, penWidth, color );
}
else
{
if( m_Fill == FILL_TYPE::FILLED_WITH_BG_BODYCOLOR )
color = aSettings->GetLayerColor( LAYER_DEVICE_BACKGROUND );
GRFilledArc( nullptr, DC, posc.x, posc.y, pt1, pt2, m_Radius, penWidth, color, color );
}
}
const EDA_RECT LIB_ARC::GetBoundingBox() const
{
int minX, minY, maxX, maxY, angleStart, angleEnd;
EDA_RECT rect;
wxPoint nullPoint, startPos, endPos, centerPos;
wxPoint normStart = m_ArcStart - m_Pos;
wxPoint normEnd = m_ArcEnd - m_Pos;
if( ( normStart == nullPoint ) || ( normEnd == nullPoint ) || ( m_Radius == 0 ) )
return rect;
endPos = DefaultTransform.TransformCoordinate( m_ArcEnd );
startPos = DefaultTransform.TransformCoordinate( m_ArcStart );
centerPos = DefaultTransform.TransformCoordinate( m_Pos );
angleStart = m_t1;
angleEnd = m_t2;
if( DefaultTransform.MapAngles( &angleStart, &angleEnd ) )
{
std::swap( endPos.x, startPos.x );
std::swap( endPos.y, startPos.y );
}
/* Start with the start and end point of the arc. */
minX = std::min( startPos.x, endPos.x );
minY = std::min( startPos.y, endPos.y );
maxX = std::max( startPos.x, endPos.x );
maxY = std::max( startPos.y, endPos.y );
/* Zero degrees is a special case. */
if( angleStart == 0 )
maxX = centerPos.x + m_Radius;
/* Arc end angle wrapped passed 360. */
if( angleStart > angleEnd )
angleEnd += 3600;
if( angleStart <= 900 && angleEnd >= 900 ) /* 90 deg */
maxY = centerPos.y + m_Radius;
if( angleStart <= 1800 && angleEnd >= 1800 ) /* 180 deg */
minX = centerPos.x - m_Radius;
if( angleStart <= 2700 && angleEnd >= 2700 ) /* 270 deg */
minY = centerPos.y - m_Radius;
if( angleStart <= 3600 && angleEnd >= 3600 ) /* 0 deg */
maxX = centerPos.x + m_Radius;
rect.SetOrigin( minX, minY );
rect.SetEnd( maxX, maxY );
rect.Inflate( ( GetPenWidth() / 2 ) + 1 );
return rect;
}
void LIB_ARC::GetMsgPanelInfo( EDA_DRAW_FRAME* aFrame, std::vector<MSG_PANEL_ITEM>& aList )
{
wxString msg;
EDA_RECT bBox = GetBoundingBox();
LIB_ITEM::GetMsgPanelInfo( aFrame, aList );
msg = MessageTextFromValue( aFrame->GetUserUnits(), m_Width );
aList.emplace_back( _( "Line Width" ), msg );
msg.Printf( wxT( "(%d, %d, %d, %d)" ), bBox.GetOrigin().x,
bBox.GetOrigin().y, bBox.GetEnd().x, bBox.GetEnd().y );
aList.emplace_back( _( "Bounding Box" ), msg );
}
wxString LIB_ARC::GetSelectMenuText( EDA_UNITS aUnits ) const
{
return wxString::Format( _( "Arc, radius %s" ),
MessageTextFromValue( aUnits, m_Radius ) );
}
BITMAP_DEF LIB_ARC::GetMenuImage() const
{
return add_arc_xpm;
}
void LIB_ARC::BeginEdit( const wxPoint aPosition )
{
m_ArcStart = m_ArcEnd = aPosition;
m_editState = 1;
}
void LIB_ARC::CalcEdit( const wxPoint& aPosition )
{
#define sq( x ) pow( x, 2 )
// Edit state 0: drawing: place ArcStart
// Edit state 1: drawing: place ArcEnd (center calculated for 90-degree subtended angle)
// Edit state 2: point editing: move ArcStart (center calculated for invariant subtended angle)
// Edit state 3: point editing: move ArcEnd (center calculated for invariant subtended angle)
// Edit state 4: point editing: move center
switch( m_editState )
{
case 0:
m_ArcStart = aPosition;
m_ArcEnd = aPosition;
m_Pos = aPosition;
m_Radius = 0;
m_t1 = 0;
m_t2 = 0;
return;
case 1:
m_ArcEnd = aPosition;
m_Radius = KiROUND( sqrt( pow( GetLineLength( m_ArcStart, m_ArcEnd ), 2 ) / 2.0 ) );
break;
case 2:
case 3:
{
wxPoint v = m_ArcStart - m_ArcEnd;
double chordBefore = sq( v.x ) + sq( v.y );
if( m_editState == 2 )
m_ArcStart = aPosition;
else
m_ArcEnd = aPosition;
v = m_ArcStart - m_ArcEnd;
double chordAfter = sq( v.x ) + sq( v.y );
double ratio = chordAfter / chordBefore;
if( ratio > 0 )
{
m_Radius = int( sqrt( m_Radius * m_Radius * ratio ) ) + 1;
m_Radius = std::max( m_Radius, int( sqrt( chordAfter ) / 2 ) + 1 );
}
break;
}
case 4:
{
double chordA = GetLineLength( m_ArcStart, aPosition );
double chordB = GetLineLength( m_ArcEnd, aPosition );
m_Radius = int( ( chordA + chordB ) / 2.0 ) + 1;
break;
}
}
// Calculate center based on start, end, and radius
//
// Let 'l' be the length of the chord and 'm' the middle point of the chord
double l = GetLineLength( m_ArcStart, m_ArcEnd );
wxPoint m = ( m_ArcStart + m_ArcEnd ) / 2;
// Calculate 'd', the vector from the chord midpoint to the center
wxPoint d;
d.x = KiROUND( sqrt( sq( m_Radius ) - sq( l/2 ) ) * ( m_ArcStart.y - m_ArcEnd.y ) / l );
d.y = KiROUND( sqrt( sq( m_Radius ) - sq( l/2 ) ) * ( m_ArcEnd.x - m_ArcStart.x ) / l );
wxPoint c1 = m + d;
wxPoint c2 = m - d;
// Solution gives us 2 centers; we need to pick one:
switch( m_editState )
{
case 1:
{
// Keep center clockwise from chord while drawing
wxPoint chordVector = twoPointVector( m_ArcStart, m_ArcEnd );
double chordAngle = ArcTangente( chordVector.y, chordVector.x );
NORMALIZE_ANGLE_POS( chordAngle );
wxPoint c1Test = c1;
RotatePoint( &c1Test, m_ArcStart, -chordAngle );
m_Pos = c1Test.x > 0 ? c2 : c1;
}
break;
case 2:
case 3:
// Pick the one closer to the old center
m_Pos = ( GetLineLength( c1, m_Pos ) < GetLineLength( c2, m_Pos ) ) ? c1 : c2;
break;
case 4:
// Pick the one closer to the mouse position
m_Pos = ( GetLineLength( c1, aPosition ) < GetLineLength( c2, aPosition ) ) ? c1 : c2;
break;
}
CalcRadiusAngles();
}
void LIB_ARC::CalcRadiusAngles()
{
wxPoint centerStartVector = twoPointVector( m_Pos, m_ArcStart );
wxPoint centerEndVector = twoPointVector( m_Pos, m_ArcEnd );
m_Radius = KiROUND( EuclideanNorm( centerStartVector ) );
// Angles in eeschema are still integers
m_t1 = KiROUND( ArcTangente( centerStartVector.y, centerStartVector.x ) );
m_t2 = KiROUND( ArcTangente( centerEndVector.y, centerEndVector.x ) );
NORMALIZE_ANGLE_POS( m_t1 );
NORMALIZE_ANGLE_POS( m_t2 ); // angles = 0 .. 3600
// Restrict angle to less than 180 to avoid PBS display mirror Trace because it is
// assumed that the arc is less than 180 deg to find orientation after rotate or mirror.
if( (m_t2 - m_t1) > 1800 )
m_t2 -= 3600;
else if( (m_t2 - m_t1) <= -1800 )
m_t2 += 3600;
while( (m_t2 - m_t1) >= 1800 )
{
m_t2--;
m_t1++;
}
while( (m_t1 - m_t2) >= 1800 )
{
m_t2++;
m_t1--;
}
NORMALIZE_ANGLE_POS( m_t1 );
if( !IsMoving() )
NORMALIZE_ANGLE_POS( m_t2 );
}
VECTOR2I LIB_ARC::CalcMidPoint() const
{
VECTOR2D midPoint;
double startAngle = static_cast<double>( m_t1 ) / 10.0;
double endAngle = static_cast<double>( m_t2 ) / 10.0;
if( endAngle < startAngle )
endAngle -= 360.0;
double midPointAngle = ( ( endAngle - startAngle ) / 2.0 ) + startAngle;
double x = cos( DEG2RAD( midPointAngle ) ) * m_Radius;
double y = sin( DEG2RAD( midPointAngle ) ) * m_Radius;
midPoint.x = KiROUND( x ) + m_Pos.x;
midPoint.y = KiROUND( y ) + m_Pos.y;
return midPoint;
}
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