kicad/include/geometry/shape_poly_set.h

1225 lines
48 KiB
C++

/*
* This program source code file is part of KiCad, a free EDA CAD application.
*
* Copyright (C) 2015-2017 CERN
* @author Tomasz Wlostowski <tomasz.wlostowski@cern.ch>
* @author Alejandro García Montoro <alejandro.garciamontoro@gmail.com>
*
* 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
*/
#ifndef __SHAPE_POLY_SET_H
#define __SHAPE_POLY_SET_H
#include <vector>
#include <cstdio>
#include <memory>
#include <geometry/shape.h>
#include <geometry/shape_line_chain.h>
#include <md5_hash.h>
/**
* Class SHAPE_POLY_SET
*
* Represents a set of closed polygons. Polygons may be nonconvex, self-intersecting
* and have holes. Provides boolean operations (using Clipper library as the backend).
*
* Let us define the terms used on this class to clarify methods names and comments:
* - Polygon: each polygon in the set.
* - Outline: first polyline in each polygon; represents its outer contour.
* - Hole: second and following polylines in the polygon.
* - Contour: each polyline of each polygon in the set, whether or not it is an
* outline or a hole.
* - Vertex (or corner): each one of the points that define a contour.
*
* TODO: add convex partitioning & spatial index
*/
class SHAPE_POLY_SET : public SHAPE
{
public:
///> represents a single polygon outline with holes. The first entry is the outline,
///> the remaining (if any), are the holes
///> N.B. SWIG only supports typedef, so avoid c++ 'using' keyword
typedef std::vector<SHAPE_LINE_CHAIN> POLYGON;
class TRIANGULATED_POLYGON
{
public:
struct TRI
{
TRI( int _a = 0, int _b = 0, int _c = 0 ) : a( _a ), b( _b ), c( _c )
{
}
int a, b, c;
};
void Clear()
{
m_vertices.clear();
m_triangles.clear();
}
void GetTriangle( int index, VECTOR2I& a, VECTOR2I& b, VECTOR2I& c ) const
{
auto tri = m_triangles[ index ];
a = m_vertices[ tri.a ];
b = m_vertices[ tri.b ];
c = m_vertices[ tri.c ];
}
void AddTriangle( const TRI& aTri )
{
m_triangles.push_back( aTri );
}
void AddTriangle( int a, int b, int c )
{
m_triangles.emplace_back( a, b, c );
}
void AddVertex( const VECTOR2I& aP )
{
m_vertices.push_back( aP );
}
size_t GetTriangleCount() const
{
return m_triangles.size();
}
size_t GetVertexCount() const
{
return m_vertices.size();
}
private:
std::deque<TRI> m_triangles;
std::deque<VECTOR2I> m_vertices;
};
/**
* Struct VERTEX_INDEX
*
* Structure to hold the necessary information in order to index a vertex on a
* SHAPE_POLY_SET object: the polygon index, the contour index relative to the polygon and
* the vertex index relative the contour.
*/
typedef struct VERTEX_INDEX
{
int m_polygon; /*!< m_polygon is the index of the polygon. */
int m_contour; /*!< m_contour is the index of the contour relative to the polygon. */
int m_vertex; /*!< m_vertex is the index of the vertex relative to the contour. */
VERTEX_INDEX() : m_polygon(-1), m_contour(-1), m_vertex(-1)
{
}
} VERTEX_INDEX;
/**
* Class ITERATOR_TEMPLATE
*
* Base class for iterating over all vertices in a given SHAPE_POLY_SET.
*/
template <class T>
class ITERATOR_TEMPLATE
{
public:
/**
* Function IsEndContour.
* @return bool - true if the current vertex is the last one of the current contour
* (outline or hole); false otherwise.
*/
bool IsEndContour() const
{
return m_currentVertex + 1 == m_poly->CPolygon( m_currentPolygon )[m_currentContour].PointCount();
}
/**
* Function IsLastOutline.
* @return bool - true if the current outline is the last one; false otherwise.
*/
bool IsLastPolygon() const
{
return m_currentPolygon == m_lastPolygon;
}
operator bool() const
{
return ( ( m_currentPolygon < m_lastPolygon ) || ( m_currentPolygon == m_poly->OutlineCount() - 1 &&
( m_currentContour < static_cast<int>( m_poly->CPolygon( m_currentPolygon ).size() ) - 1 ||
( m_currentVertex < m_poly->CPolygon( m_currentPolygon )[m_currentContour].PointCount() )
)
) );
}
/**
* Function Advance
* advances the indices of the current vertex/outline/contour, checking whether the
* vertices in the holes have to be iterated through
*/
void Advance()
{
// Advance vertex index
m_currentVertex ++;
// Check whether the user wants to iterate through the vertices of the holes
// and behave accordingly
if( m_iterateHoles )
{
// If the last vertex of the contour was reached, advance the contour index
if( m_currentVertex >= m_poly->CPolygon( m_currentPolygon )[m_currentContour].PointCount() )
{
m_currentVertex = 0;
m_currentContour++;
// If the last contour of the current polygon was reached, advance the
// outline index
int totalContours = m_poly->CPolygon( m_currentPolygon ).size();
if( m_currentContour >= totalContours )
{
m_currentContour = 0;
m_currentPolygon++;
}
}
}
else
{
// If the last vertex of the outline was reached, advance to the following polygon
if( m_currentVertex >= m_poly->CPolygon( m_currentPolygon )[0].PointCount() )
{
m_currentVertex = 0;
m_currentPolygon++;
}
}
}
void operator++( int dummy )
{
Advance();
}
void operator++()
{
Advance();
}
T& Get()
{
return m_poly->Polygon( m_currentPolygon )[m_currentContour].Point( m_currentVertex );
}
T& operator*()
{
return Get();
}
T* operator->()
{
return &Get();
}
/**
* Function GetIndex
* @return VERTEX_INDEX - indices of the current polygon, contour and vertex.
*/
VERTEX_INDEX GetIndex()
{
VERTEX_INDEX index;
index.m_polygon = m_currentPolygon;
index.m_contour = m_currentContour;
index.m_vertex = m_currentVertex;
return index;
}
private:
friend class SHAPE_POLY_SET;
SHAPE_POLY_SET* m_poly;
int m_currentPolygon;
int m_currentContour;
int m_currentVertex;
int m_lastPolygon;
bool m_iterateHoles;
};
/**
* Class SEGMENT_ITERATOR_TEMPLATE
*
* Base class for iterating over all segments in a given SHAPE_POLY_SET.
*/
template <class T>
class SEGMENT_ITERATOR_TEMPLATE
{
public:
/**
* Function IsLastOutline.
* @return bool - true if the current outline is the last one.
*/
bool IsLastPolygon() const
{
return m_currentPolygon == m_lastPolygon;
}
operator bool() const
{
return m_currentPolygon <= m_lastPolygon;
}
/**
* Function Advance
* advances the indices of the current vertex/outline/contour, checking whether the
* vertices in the holes have to be iterated through
*/
void Advance()
{
// Advance vertex index
m_currentSegment++;
int last;
// Check whether the user wants to iterate through the vertices of the holes
// and behave accordingly
if( m_iterateHoles )
{
last = m_poly->CPolygon( m_currentPolygon )[m_currentContour].SegmentCount();
// If the last vertex of the contour was reached, advance the contour index
if( m_currentSegment >= last )
{
m_currentSegment = 0;
m_currentContour++;
// If the last contour of the current polygon was reached, advance the
// outline index
int totalContours = m_poly->CPolygon( m_currentPolygon ).size();
if( m_currentContour >= totalContours )
{
m_currentContour = 0;
m_currentPolygon++;
}
}
}
else
{
last = m_poly->CPolygon( m_currentPolygon )[0].SegmentCount();
// If the last vertex of the outline was reached, advance to the following
// polygon
if( m_currentSegment >= last )
{
m_currentSegment = 0;
m_currentPolygon++;
}
}
}
void operator++( int dummy )
{
Advance();
}
void operator++()
{
Advance();
}
T Get()
{
return m_poly->Polygon( m_currentPolygon )[m_currentContour].Segment( m_currentSegment );
}
T operator*()
{
return Get();
}
/**
* Function GetIndex
* @return VERTEX_INDEX - indices of the current polygon, contour and vertex.
*/
VERTEX_INDEX GetIndex()
{
VERTEX_INDEX index;
index.m_polygon = m_currentPolygon;
index.m_contour = m_currentContour;
index.m_vertex = m_currentSegment;
return index;
}
/**
* Function IsAdjacent
* @param aOther is an iterator pointing to another segment.
* @return bool - true if both iterators point to the same segment of the same
* contour of the same polygon of the same polygon set; false
* otherwise.
*/
bool IsAdjacent( SEGMENT_ITERATOR_TEMPLATE<T> aOther )
{
// Check that both iterators point to the same contour of the same polygon of the
// same polygon set
if( m_poly == aOther.m_poly && m_currentPolygon == aOther.m_currentPolygon &&
m_currentContour == aOther.m_currentContour )
{
// Compute the total number of segments
int numSeg;
numSeg = m_poly->CPolygon( m_currentPolygon )[m_currentContour].SegmentCount();
// Compute the difference of the segment indices. If it is exactly one, they
// are adjacent. The only missing case where they also are adjacent is when
// the segments are the first and last one, in which case the difference
// always equals the total number of segments minus one.
int indexDiff = abs( m_currentSegment - aOther.m_currentSegment );
return ( indexDiff == 1 ) || ( indexDiff == (numSeg - 1) );
}
return false;
}
private:
friend class SHAPE_POLY_SET;
SHAPE_POLY_SET* m_poly;
int m_currentPolygon;
int m_currentContour;
int m_currentSegment;
int m_lastPolygon;
bool m_iterateHoles;
};
// Iterator and const iterator types to visit polygon's points.
typedef ITERATOR_TEMPLATE<VECTOR2I> ITERATOR;
typedef ITERATOR_TEMPLATE<const VECTOR2I> CONST_ITERATOR;
// Iterator and const iterator types to visit polygon's edges.
typedef SEGMENT_ITERATOR_TEMPLATE<SEG> SEGMENT_ITERATOR;
typedef SEGMENT_ITERATOR_TEMPLATE<const SEG> CONST_SEGMENT_ITERATOR;
SHAPE_POLY_SET();
/**
* Copy constructor SHAPE_POLY_SET
* Performs a deep copy of \p aOther into \p this.
* @param aOther is the SHAPE_POLY_SET object that will be copied.
* @param aDeepCopy if true, make new copies of the triangulated unique_ptr vector
*/
SHAPE_POLY_SET( const SHAPE_POLY_SET& aOther, bool aDeepCopy = false );
~SHAPE_POLY_SET();
/**
* Function GetRelativeIndices
*
* Converts a global vertex index ---i.e., a number that globally identifies a vertex in a
* concatenated list of all vertices in all contours--- and get the index of the vertex
* relative to the contour relative to the polygon in which it is.
* @param aGlobalIdx is the global index of the corner whose structured index wants to
* be found
* @param aRelativeIndices is a pointer to the set of relative indices to store.
* @return bool - true if the global index is correct and the information in
* aRelativeIndices is valid; false otherwise.
*/
bool GetRelativeIndices( int aGlobalIdx, VERTEX_INDEX* aRelativeIndices) const;
/**
* Function GetGlobalIndex
* computes the global index of a vertex from the relative indices of polygon, contour and
* vertex.
* @param aRelativeIndices is the set of relative indices.
* @param aGlobalIdx [out] is the computed global index.
* @return bool - true if the relative indices are correct; false otherwise. The computed
* global index is returned in the \p aGlobalIdx reference.
*/
bool GetGlobalIndex( VERTEX_INDEX aRelativeIndices, int& aGlobalIdx );
/// @copydoc SHAPE::Clone()
SHAPE* Clone() const override;
///> Creates a new empty polygon in the set and returns its index
int NewOutline();
///> Creates a new hole in a given outline
int NewHole( int aOutline = -1 );
///> Adds a new outline to the set and returns its index
int AddOutline( const SHAPE_LINE_CHAIN& aOutline );
///> Adds a new hole to the given outline (default: last) and returns its index
int AddHole( const SHAPE_LINE_CHAIN& aHole, int aOutline = -1 );
///> Appends a vertex at the end of the given outline/hole (default: the last outline)
/**
* Function Append
* adds a new vertex to the contour indexed by \p aOutline and \p aHole (defaults to the
* outline of the last polygon).
* @param x is the x coordinate of the new vertex.
* @param y is the y coordinate of the new vertex.
* @param aOutline is the index of the polygon.
* @param aHole is the index of the hole (-1 for the main outline),
* @param aAllowDuplication is a flag to indicate whether it is allowed to add this
* corner even if it is duplicated.
* @return int - the number of corners of the selected contour after the addition.
*/
int Append( int x, int y, int aOutline = -1, int aHole = -1,
bool aAllowDuplication = false );
///> Merges polygons from two sets.
void Append( const SHAPE_POLY_SET& aSet );
///> Appends a vertex at the end of the given outline/hole (default: the last outline)
void Append( const VECTOR2I& aP, int aOutline = -1, int aHole = -1 );
/**
* Function InsertVertex
* Adds a vertex in the globally indexed position aGlobalIndex.
* @param aGlobalIndex is the global index of the position in which teh new vertex will be
* inserted.
* @param aNewVertex is the new inserted vertex.
*/
void InsertVertex( int aGlobalIndex, VECTOR2I aNewVertex );
///> Returns the index-th vertex in a given hole outline within a given outline
VECTOR2I& Vertex( int aIndex, int aOutline, int aHole );
///> Returns the index-th vertex in a given hole outline within a given outline
const VECTOR2I& CVertex( int aIndex, int aOutline, int aHole ) const;
///> Returns the aGlobalIndex-th vertex in the poly set
VECTOR2I& Vertex( int aGlobalIndex );
///> Returns the aGlobalIndex-th vertex in the poly set
const VECTOR2I& CVertex( int aGlobalIndex ) const;
///> Returns the index-th vertex in a given hole outline within a given outline
VECTOR2I& Vertex( VERTEX_INDEX aIndex );
///> Returns the index-th vertex in a given hole outline within a given outline
const VECTOR2I& CVertex( VERTEX_INDEX aIndex ) const;
/**
* Returns the global indexes of the previous and the next corner
* of the aGlobalIndex-th corner of a contour in the polygon set.
* they are often aGlobalIndex-1 and aGlobalIndex+1, but not for the first and last
* corner of the contour.
* @param aGlobalIndex is index of the corner, globally indexed between all edges in all
* contours
* @param aPrevious - the globalIndex of the previous corner of the same contour.
* @param aNext - the globalIndex of the next corner of the same contour.
* @return true if OK, false if aGlobalIndex is out of range
*/
bool GetNeighbourIndexes( int aGlobalIndex, int* aPrevious, int* aNext );
/**
* Function IsPolygonSelfIntersecting.
* Checks whether the aPolygonIndex-th polygon in the set is self intersecting.
* @param aPolygonIndex index of the polygon that wants to be checked.
* @return bool - true if the aPolygonIndex-th polygon is self intersecting, false
* otherwise.
*/
bool IsPolygonSelfIntersecting( int aPolygonIndex );
/**
* Function IsSelfIntersecting
* Checks whether any of the polygons in the set is self intersecting.
* @return bool - true if any of the polygons is self intersecting, false otherwise.
*/
bool IsSelfIntersecting();
///> Returns the number of triangulated polygons
unsigned int TriangulatedPolyCount() const { return m_triangulatedPolys.size(); }
///> Returns the number of outlines in the set
int OutlineCount() const { return m_polys.size(); }
///> Returns the number of vertices in a given outline/hole
int VertexCount( int aOutline = -1, int aHole = -1 ) const;
///> Returns the number of holes in a given outline
int HoleCount( int aOutline ) const
{
if( ( aOutline < 0 ) || (aOutline >= (int)m_polys.size()) || (m_polys[aOutline].size() < 2) )
return 0;
// the first polygon in m_polys[aOutline] is the main contour,
// only others are holes:
return m_polys[aOutline].size() - 1;
}
///> Returns the reference to aIndex-th outline in the set
SHAPE_LINE_CHAIN& Outline( int aIndex )
{
return m_polys[aIndex][0];
}
/**
* Function Subset
* returns a subset of the polygons in this set, the ones between aFirstPolygon and
* aLastPolygon.
* @param aFirstPolygon is the first polygon to be included in the returned set.
* @param aLastPolygon is the first polygon to be excluded of the returned set.
* @return SHAPE_POLY_SET - a set containing the polygons between aFirstPolygon (included)
* and aLastPolygon (excluded).
*/
SHAPE_POLY_SET Subset( int aFirstPolygon, int aLastPolygon );
SHAPE_POLY_SET UnitSet( int aPolygonIndex )
{
return Subset( aPolygonIndex, aPolygonIndex + 1 );
}
///> Returns the reference to aHole-th hole in the aIndex-th outline
SHAPE_LINE_CHAIN& Hole( int aOutline, int aHole )
{
return m_polys[aOutline][aHole + 1];
}
///> Returns the aIndex-th subpolygon in the set
POLYGON& Polygon( int aIndex )
{
return m_polys[aIndex];
}
const POLYGON& Polygon( int aIndex ) const
{
return m_polys[aIndex];
}
const TRIANGULATED_POLYGON* TriangulatedPolygon( int aIndex ) const
{
return m_triangulatedPolys[aIndex].get();
}
const SHAPE_LINE_CHAIN& COutline( int aIndex ) const
{
return m_polys[aIndex][0];
}
const SHAPE_LINE_CHAIN& CHole( int aOutline, int aHole ) const
{
return m_polys[aOutline][aHole + 1];
}
const POLYGON& CPolygon( int aIndex ) const
{
return m_polys[aIndex];
}
/**
* Function Iterate
* returns an object to iterate through the points of the polygons between \p aFirst and
* \p aLast.
* @param aFirst is the first polygon whose points will be iterated.
* @param aLast is the last polygon whose points will be iterated.
* @param aIterateHoles is a flag to indicate whether the points of the holes should be
* iterated.
* @return ITERATOR - the iterator object.
*/
ITERATOR Iterate( int aFirst, int aLast, bool aIterateHoles = false )
{
ITERATOR iter;
iter.m_poly = this;
iter.m_currentPolygon = aFirst;
iter.m_lastPolygon = aLast < 0 ? OutlineCount() - 1 : aLast;
iter.m_currentContour = 0;
iter.m_currentVertex = 0;
iter.m_iterateHoles = aIterateHoles;
return iter;
}
/**
* Function Iterate
* @param aOutline the index of the polygon to be iterated.
* @return ITERATOR - an iterator object to visit all points in the main outline of the
* aOutline-th polygon, without visiting the points in the holes.
*/
ITERATOR Iterate( int aOutline )
{
return Iterate( aOutline, aOutline );
}
/**
* Function IterateWithHoles
* @param aOutline the index of the polygon to be iterated.
* @return ITERATOR - an iterator object to visit all points in the main outline of the
* aOutline-th polygon, visiting also the points in the holes.
*/
ITERATOR IterateWithHoles( int aOutline )
{
return Iterate( aOutline, aOutline, true );
}
/**
* Function Iterate
* @return ITERATOR - an iterator object to visit all points in all outlines of the set,
* without visiting the points in the holes.
*/
ITERATOR Iterate()
{
return Iterate( 0, OutlineCount() - 1 );
}
/**
* Function IterateWithHoles
* @return ITERATOR - an iterator object to visit all points in all outlines of the set,
* visiting also the points in the holes.
*/
ITERATOR IterateWithHoles()
{
return Iterate( 0, OutlineCount() - 1, true );
}
CONST_ITERATOR CIterate( int aFirst, int aLast, bool aIterateHoles = false ) const
{
CONST_ITERATOR iter;
iter.m_poly = const_cast<SHAPE_POLY_SET*>( this );
iter.m_currentPolygon = aFirst;
iter.m_lastPolygon = aLast < 0 ? OutlineCount() - 1 : aLast;
iter.m_currentContour = 0;
iter.m_currentVertex = 0;
iter.m_iterateHoles = aIterateHoles;
return iter;
}
CONST_ITERATOR CIterate( int aOutline ) const
{
return CIterate( aOutline, aOutline );
}
CONST_ITERATOR CIterateWithHoles( int aOutline ) const
{
return CIterate( aOutline, aOutline, true );
}
CONST_ITERATOR CIterate() const
{
return CIterate( 0, OutlineCount() - 1 );
}
CONST_ITERATOR CIterateWithHoles() const
{
return CIterate( 0, OutlineCount() - 1, true );
}
ITERATOR IterateFromVertexWithHoles( int aGlobalIdx )
{
// Build iterator
ITERATOR iter = IterateWithHoles();
// Get the relative indices of the globally indexed vertex
VERTEX_INDEX indices;
if( !GetRelativeIndices( aGlobalIdx, &indices ) )
throw( std::out_of_range( "aGlobalIndex-th vertex does not exist" ) );
// Adjust where the iterator is pointing
iter.m_currentPolygon = indices.m_polygon;
iter.m_currentContour = indices.m_contour;
iter.m_currentVertex = indices.m_vertex;
return iter;
}
///> Returns an iterator object, for iterating between aFirst and aLast outline, with or
/// without holes (default: without)
SEGMENT_ITERATOR IterateSegments( int aFirst, int aLast, bool aIterateHoles = false )
{
SEGMENT_ITERATOR iter;
iter.m_poly = this;
iter.m_currentPolygon = aFirst;
iter.m_lastPolygon = aLast < 0 ? OutlineCount() - 1 : aLast;
iter.m_currentContour = 0;
iter.m_currentSegment = 0;
iter.m_iterateHoles = aIterateHoles;
return iter;
}
///> Returns an iterator object, for iterating aPolygonIdx-th polygon edges
SEGMENT_ITERATOR IterateSegments( int aPolygonIdx )
{
return IterateSegments( aPolygonIdx, aPolygonIdx );
}
///> Returns an iterator object, for all outlines in the set (no holes)
SEGMENT_ITERATOR IterateSegments()
{
return IterateSegments( 0, OutlineCount() - 1 );
}
///> Returns an iterator object, for all outlines in the set (with holes)
SEGMENT_ITERATOR IterateSegmentsWithHoles()
{
return IterateSegments( 0, OutlineCount() - 1, true );
}
///> Returns an iterator object, for the aOutline-th outline in the set (with holes)
SEGMENT_ITERATOR IterateSegmentsWithHoles( int aOutline )
{
return IterateSegments( aOutline, aOutline, true );
}
/** operations on polygons use a aFastMode param
* if aFastMode is PM_FAST (true) the result can be a weak polygon
* if aFastMode is PM_STRICTLY_SIMPLE (false) (default) the result is (theorically) a strictly
* simple polygon, but calculations can be really significantly time consuming
* Most of time PM_FAST is preferable.
* PM_STRICTLY_SIMPLE can be used in critical cases (Gerber output for instance)
*/
enum POLYGON_MODE
{
PM_FAST = true,
PM_STRICTLY_SIMPLE = false
};
///> Performs boolean polyset union
///> For aFastMode meaning, see function booleanOp
void BooleanAdd( const SHAPE_POLY_SET& b, POLYGON_MODE aFastMode );
///> Performs boolean polyset difference
///> For aFastMode meaning, see function booleanOp
void BooleanSubtract( const SHAPE_POLY_SET& b, POLYGON_MODE aFastMode );
///> Performs boolean polyset intersection
///> For aFastMode meaning, see function booleanOp
void BooleanIntersection( const SHAPE_POLY_SET& b, POLYGON_MODE aFastMode );
///> Performs boolean polyset union between a and b, store the result in it self
///> For aFastMode meaning, see function booleanOp
void BooleanAdd( const SHAPE_POLY_SET& a, const SHAPE_POLY_SET& b,
POLYGON_MODE aFastMode );
///> Performs boolean polyset difference between a and b, store the result in it self
///> For aFastMode meaning, see function booleanOp
void BooleanSubtract( const SHAPE_POLY_SET& a, const SHAPE_POLY_SET& b,
POLYGON_MODE aFastMode );
///> Performs boolean polyset intersection between a and b, store the result in it self
///> For aFastMode meaning, see function booleanOp
void BooleanIntersection( const SHAPE_POLY_SET& a, const SHAPE_POLY_SET& b,
POLYGON_MODE aFastMode );
/**
* Performs outline inflation/deflation, using (optionally) round corners.
* Polygons can have holes, but not linked holes with main outlines,
* if aFactor < 0.
* When aFactor is < 0 a bad shape can result from these extra-segments used to
* link holes to main outlines
* Use InflateWithLinkedHoles for these polygons, especially if aFactor < 0
*
* @param aFactor - number of units to offset edges
* @param aCircleSegmentsCount - number of segments per 360° to use in curve approx
* @param aPreseveCorners - If true, use square joints to keep angles preserved
*/
void Inflate( int aFactor, int aCircleSegmentsCount, bool aPreseveCorners = false );
void Inflate( int aFactor, bool aPreseveCorners )
{
Inflate( aFactor, 32, aPreseveCorners );
}
///> Performs outline inflation/deflation, using round corners.
///> Polygons can have holes, and/or linked holes with main outlines.
///> The resulting polygons are laso polygons with linked holes to main outlines
///> For aFastMode meaning, see function booleanOp
void InflateWithLinkedHoles( int aFactor, int aCircleSegmentsCount, POLYGON_MODE aFastMode );
///> Converts a set of polygons with holes to a singe outline with "slits"/"fractures"
///> connecting the outer ring to the inner holes
///> For aFastMode meaning, see function booleanOp
void Fracture( POLYGON_MODE aFastMode );
///> Converts a single outline slitted ("fractured") polygon into a set ouf outlines
///> with holes.
void Unfracture( POLYGON_MODE aFastMode );
///> Returns true if the polygon set has any holes.
bool HasHoles() const;
///> Returns true if the polygon set has any holes tha share a vertex.
bool HasTouchingHoles() const;
///> Simplifies the polyset (merges overlapping polys, eliminates degeneracy/self-intersections)
///> For aFastMode meaning, see function booleanOp
void Simplify( POLYGON_MODE aFastMode );
/**
* Function NormalizeAreaOutlines
* Convert a self-intersecting polygon to one (or more) non self-intersecting polygon(s)
* Removes null segments.
* @return int - the polygon count (always >= 1, because there is at least one polygon)
* There are new polygons only if the polygon count is > 1.
*/
int NormalizeAreaOutlines();
/// @copydoc SHAPE::Format()
const std::string Format() const override;
/// @copydoc SHAPE::Parse()
bool Parse( std::stringstream& aStream ) override;
/// @copydoc SHAPE::Move()
void Move( const VECTOR2I& aVector ) override;
/**
* Function Rotate
* rotates all vertices by a given angle
* @param aCenter is the rotation center
* @param aAngle rotation angle in radians
*/
void Rotate( double aAngle, const VECTOR2I& aCenter );
/// @copydoc SHAPE::IsSolid()
bool IsSolid() const override
{
return true;
}
const BOX2I BBox( int aClearance = 0 ) const override;
/**
* Function PointOnEdge()
*
* Checks if point aP lies on an edge or vertex of some of the outlines or holes.
* @param aP is the point to check.
* @return bool - true if the point lies on the edge of any polygon.
*/
bool PointOnEdge( const VECTOR2I& aP ) const;
/**
* Function Collide
* Checks whether the point aP collides with the inside of the polygon set; if the point
* lies on an edge or on a corner of any of the polygons, there is no collision: the edges
* does not belong to the polygon itself.
* @param aP is the VECTOR2I point whose collision with respect to the poly set
* will be tested.
* @param aClearance is the security distance; if the point lies closer to the polygon
* than aClearance distance, then there is a collision.
* @return bool - true if the point aP collides with the polygon; false in any other case.
*/
bool Collide( const VECTOR2I& aP, int aClearance = 0 ) const override;
/**
* Function Collide
* Checks whether the segment aSeg collides with the inside of the polygon set; if the
* segment touches an edge or a corner of any of the polygons, there is no collision:
* the edges do not belong to the polygon itself.
* @param aSeg is the SEG segment whose collision with respect to the poly set
* will be tested.
* @param aClearance is the security distance; if the segment passes closer to the polygon
* than aClearance distance, then there is a collision.
* @return bool - true if the segment aSeg collides with the polygon;
* false in any other case.
*/
bool Collide( const SEG& aSeg, int aClearance = 0 ) const override;
/**
* Function CollideVertex
* Checks whether aPoint collides with any vertex of any of the contours of the polygon.
* @param aPoint is the VECTOR2I point whose collision with respect to the polygon
* will be tested.
* @param aClearance is the security distance; if \p aPoint lies closer to a vertex than
* aClearance distance, then there is a collision.
* @param aClosestVertex is the index of the closes vertex to \p aPoint.
* @return bool - true if there is a collision, false in any other case.
*/
bool CollideVertex( const VECTOR2I& aPoint, VERTEX_INDEX& aClosestVertex,
int aClearance = 0 );
/**
* Function CollideEdge
* Checks whether aPoint collides with any edge of any of the contours of the polygon.
* @param aPoint is the VECTOR2I point whose collision with respect to the polygon
* will be tested.
* @param aClearance is the security distance; if \p aPoint lies closer to a vertex than
* aClearance distance, then there is a collision.
* @param aClosestVertex is the index of the closes vertex to \p aPoint.
* @return bool - true if there is a collision, false in any other case.
*/
bool CollideEdge( const VECTOR2I& aPoint, VERTEX_INDEX& aClosestVertex,
int aClearance = 0 );
/**
* Returns true if a given subpolygon contains the point aP
*
* @param aP is the point to check
* @param aSubpolyIndex is the subpolygon to check, or -1 to check all
* @param aIgnoreHoles controls whether or not internal holes are considered
* @param aIgnoreEdges controls whether or not a check for the point lying exactly on
* the polygon edge is made
* @return true if the polygon contains the point
*/
bool Contains( const VECTOR2I& aP, int aSubpolyIndex = -1, bool aIgnoreHoles = false,
bool aIgnoreEdges = false ) const;
///> Returns true if the set is empty (no polygons at all)
bool IsEmpty() const
{
return m_polys.size() == 0;
}
/**
* Function RemoveVertex
* deletes the aGlobalIndex-th vertex.
* @param aGlobalIndex is the global index of the to-be-removed vertex.
*/
void RemoveVertex( int aGlobalIndex );
/**
* Function RemoveVertex
* deletes the vertex indexed by aIndex (index of polygon, contour and vertex).
* @param aRelativeIndices is the set of relative indices of the to-be-removed vertex.
*/
void RemoveVertex( VERTEX_INDEX aRelativeIndices );
///> Removes all outlines & holes (clears) the polygon set.
void RemoveAllContours();
/**
* Function RemoveContour
* deletes the aContourIdx-th contour of the aPolygonIdx-th polygon in the set.
* @param aContourIdx is the index of the contour in the aPolygonIdx-th polygon to be
* removed.
* @param aPolygonIdx is the index of the polygon in which the to-be-removed contour is.
* Defaults to the last polygon in the set.
*/
void RemoveContour( int aContourIdx, int aPolygonIdx = -1 );
/**
* Function RemoveNullSegments
* looks for null segments; ie, segments whose ends are exactly the same and deletes them.
* @return int - the number of deleted segments.
*/
int RemoveNullSegments();
///> Returns total number of vertices stored in the set.
int TotalVertices() const;
///> Deletes aIdx-th polygon from the set
void DeletePolygon( int aIdx );
/**
* Function Chamfer
* returns a chamfered version of the aIndex-th polygon.
* @param aDistance is the chamfering distance.
* @param aIndex is the index of the polygon to be chamfered.
* @return POLYGON - A polygon containing the chamfered version of the aIndex-th polygon.
*/
POLYGON ChamferPolygon( unsigned int aDistance, int aIndex = 0 );
/**
* Function Fillet
* returns a filleted version of the aIndex-th polygon.
* @param aRadius is the fillet radius.
* @param aErrorMax is the maximum allowable deviation of the polygon from the circle
* @param aIndex is the index of the polygon to be filleted
* @return POLYGON - A polygon containing the filleted version of the aIndex-th polygon.
*/
POLYGON FilletPolygon( unsigned int aRadius, int aErrorMax, int aIndex = 0 );
/**
* Function Chamfer
* returns a chamfered version of the polygon set.
* @param aDistance is the chamfering distance.
* @return SHAPE_POLY_SET - A set containing the chamfered version of this set.
*/
SHAPE_POLY_SET Chamfer( int aDistance );
/**
* Function Fillet
* returns a filleted version of the polygon set.
* @param aRadius is the fillet radius.
* @param aErrorMax is the maximum allowable deviation of the polygon from the circle
* @return SHAPE_POLY_SET - A set containing the filleted version of this set.
*/
SHAPE_POLY_SET Fillet( int aRadius, int aErrorMax );
/**
* Function DistanceToPolygon
* computes the minimum distance between the aIndex-th polygon and aPoint.
* @param aPoint is the point whose distance to the aIndex-th polygon has to be measured.
* @param aIndex is the index of the polygon whose distace to aPoint has to be measured.
* @return int - The minimum distance between aPoint and all the segments of the aIndex-th
* polygon. If the point is contained in the polygon, the distance is zero.
*/
int DistanceToPolygon( VECTOR2I aPoint, int aIndex );
/**
* Function DistanceToPolygon
* computes the minimum distance between the aIndex-th polygon and aSegment with a
* possible width.
* @param aSegment is the segment whose distance to the aIndex-th polygon has to be
* measured.
* @param aIndex is the index of the polygon whose distace to aPoint has to be measured.
* @param aSegmentWidth is the width of the segment; defaults to zero.
* @return int - The minimum distance between aSegment and all the segments of the
* aIndex-th polygon. If the point is contained in the polygon, the
* distance is zero.
*/
int DistanceToPolygon( SEG aSegment, int aIndex, int aSegmentWidth = 0 );
/**
* Function DistanceToPolygon
* computes the minimum distance between aPoint and all the polygons in the set
* @param aPoint is the point whose distance to the set has to be measured.
* @return int - The minimum distance between aPoint and all the polygons in the set. If
* the point is contained in any of the polygons, the distance is zero.
*/
int Distance( VECTOR2I aPoint );
/**
* Function DistanceToPolygon
* computes the minimum distance between aSegment and all the polygons in the set.
* @param aSegment is the segment whose distance to the polygon set has to be measured.
* @param aSegmentWidth is the width of the segment; defaults to zero.
* @return int - The minimum distance between aSegment and all the polygons in the set.
* If the point is contained in the polygon, the distance is zero.
*/
int Distance( const SEG& aSegment, int aSegmentWidth = 0 );
/**
* Function IsVertexInHole.
* checks whether the aGlobalIndex-th vertex belongs to a hole.
* @param aGlobalIdx is the index of the vertex.
* @return bool - true if the globally indexed aGlobalIdx-th vertex belongs to a hole.
*/
bool IsVertexInHole( int aGlobalIdx );
private:
SHAPE_LINE_CHAIN& getContourForCorner( int aCornerId, int& aIndexWithinContour );
VECTOR2I& vertex( int aCornerId );
const VECTOR2I& cvertex( int aCornerId ) const;
void fractureSingle( POLYGON& paths );
void unfractureSingle ( POLYGON& path );
void importTree( ClipperLib::PolyTree* tree );
/** Function booleanOp
* this is the engine to execute all polygon boolean transforms
* (AND, OR, ... and polygon simplification (merging overlaping polygons)
* @param aType is the transform type ( see ClipperLib::ClipType )
* @param aOtherShape is the SHAPE_LINE_CHAIN to combine with me.
* @param aFastMode is an option to choose if the result can be a weak polygon
* or a stricty simple polygon.
* if aFastMode is PM_FAST the result can be a weak polygon
* if aFastMode is PM_STRICTLY_SIMPLE (default) the result is (theorically) a strictly
* simple polygon, but calculations can be really significantly time consuming
*/
void booleanOp( ClipperLib::ClipType aType, const SHAPE_POLY_SET& aOtherShape,
POLYGON_MODE aFastMode );
void booleanOp( ClipperLib::ClipType aType, const SHAPE_POLY_SET& aShape,
const SHAPE_POLY_SET& aOtherShape, POLYGON_MODE aFastMode );
bool pointInPolygon( const VECTOR2I& aP, const SHAPE_LINE_CHAIN& aPath,
bool aIgnoreEdges ) const;
/**
* containsSingle function
* Checks whether the point aP is inside the aSubpolyIndex-th polygon of the polyset. If
* the points lies on an edge, the polygon is considered to contain it.
* @param aP is the VECTOR2I point whose position with respect to the inside of
* the aSubpolyIndex-th polygon will be tested.
* @param aSubpolyIndex is an integer specifying which polygon in the set has to be
* checked.
* @param aIgnoreHoles can be set to true to ignore internal holes in the polygon
* @param aIgnoreEdges can be set to true to skip checking whether or not the point
* lies directly on the edge
* @return bool - true if aP is inside aSubpolyIndex-th polygon; false in any other
* case.
*/
bool containsSingle( const VECTOR2I& aP, int aSubpolyIndex, bool aIgnoreHoles = false,
bool aIgnoreEdges = false ) const;
/**
* Operations ChamferPolygon and FilletPolygon are computed under the private chamferFillet
* method; this enum is defined to make the necessary distinction when calling this method
* from the public ChamferPolygon and FilletPolygon methods.
*/
enum CORNER_MODE
{
CHAMFERED,
FILLETED
};
/**
* Function chamferFilletPolygon
* Returns the camfered or filleted version of the aIndex-th polygon in the set, depending
* on the aMode selected
* @param aMode represent which action will be taken: CORNER_MODE::CHAMFERED will
* return a chamfered version of the polygon, CORNER_MODE::FILLETED will
* return a filleted version of the polygon.
* @param aDistance is the chamfering distance if aMode = CHAMFERED; if aMode = FILLETED,
* is the filleting radius.
* @param aIndex is the index of the polygon that will be chamfered/filleted.
* @param aErrorMax is the maximum allowable deviation of the polygon from the circle
* if aMode = FILLETED. If aMode = CHAMFERED, it is unused.
* @return POLYGON - the chamfered/filleted version of the polygon.
*/
POLYGON chamferFilletPolygon( CORNER_MODE aMode, unsigned int aDistance,
int aIndex, int aErrorMax );
///> Returns true if the polygon set has any holes that touch share a vertex.
bool hasTouchingHoles( const POLYGON& aPoly ) const;
typedef std::vector<POLYGON> POLYSET;
POLYSET m_polys;
public:
SHAPE_POLY_SET& operator=( const SHAPE_POLY_SET& );
void CacheTriangulation();
bool IsTriangulationUpToDate() const;
MD5_HASH GetHash() const;
private:
MD5_HASH checksum() const;
std::vector<std::unique_ptr<TRIANGULATED_POLYGON>> m_triangulatedPolys;
bool m_triangulationValid = false;
MD5_HASH m_hash;
};
#endif