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# include <assert.h>
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# include <stdint.h>
# include <algorithm>
# include <cmath>
# include <limits>
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# include <boost/static_assert.hpp>
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# include "../ClipperUtils.hpp"
# include "../ExPolygon.hpp"
# include "../Surface.hpp"
# include "FillRectilinear2.hpp"
# ifdef SLIC3R_DEBUG
# include "SVG.hpp"
# endif
# if defined(SLIC3R_DEBUG) and defined(_WIN32)
# include <Windows.h>
# pragma comment(lib, "user32.lib")
static inline void assert_fail ( const char * assertion , const char * file , unsigned line , const char * function )
{
printf ( " Assert: %s in function %s \n file %s:%d \n " , assertion , function , file , line ) ;
if ( IsDebuggerPresent ( ) ) {
DebugBreak ( ) ;
} else {
ExitProcess ( - 1 ) ;
}
}
# undef assert
# define assert(expr) \
( ( expr ) \
? static_cast < void > ( 0 ) \
: assert_fail ( # expr , __FILE__ , __LINE__ , __FUNCTION__ ) )
# endif /* SLIC3R_DEBUG */
namespace Slic3r {
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# ifndef clamp
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template < typename T >
static inline T clamp ( T low , T high , T x )
{
return std : : max < T > ( low , std : : min < T > ( high , x ) ) ;
}
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# endif /* clamp */
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# ifndef sqr
template < typename T >
static inline T sqr ( T x )
{
return x * x ;
}
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# endif /* sqr */
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# ifndef mag2
static inline coordf_t mag2 ( const Point & p )
{
return sqr ( coordf_t ( p . x ) ) + sqr ( coordf_t ( p . y ) ) ;
}
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# endif /* mag2 */
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# ifndef mag
static inline coordf_t mag ( const Point & p )
{
return std : : sqrt ( mag2 ( p ) ) ;
}
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# endif /* mag */
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enum Orientation
{
ORIENTATION_CCW = 1 ,
ORIENTATION_CW = - 1 ,
ORIENTATION_COLINEAR = 0
} ;
// Return orientation of the three points (clockwise, counter-clockwise, colinear)
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// The predicate is exact for the coord_t type, using 64bit signed integers for the temporaries.
//FIXME Make sure the temporaries do not overflow,
// which means, the coord_t types must not have some of the topmost bits utilized.
static inline Orientation orient ( const Point & a , const Point & b , const Point & c )
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{
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BOOST_STATIC_ASSERT ( sizeof ( coord_t ) * 2 = = sizeof ( int64_t ) ) ;
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int64_t u = int64_t ( b . x ) * int64_t ( c . y ) - int64_t ( b . y ) * int64_t ( c . x ) ;
int64_t v = int64_t ( a . x ) * int64_t ( c . y ) - int64_t ( a . y ) * int64_t ( c . x ) ;
int64_t w = int64_t ( a . x ) * int64_t ( b . y ) - int64_t ( a . y ) * int64_t ( b . x ) ;
int64_t d = u - v + w ;
return ( d > 0 ) ? ORIENTATION_CCW : ( ( d = = 0 ) ? ORIENTATION_COLINEAR : ORIENTATION_CW ) ;
}
// Return orientation of the polygon.
// The input polygon must not contain duplicate points.
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static inline bool is_ccw ( const Polygon & poly )
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{
// The polygon shall be at least a triangle.
assert ( poly . points . size ( ) > = 3 ) ;
if ( poly . points . size ( ) < 3 )
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return true ;
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// 1) Find the lowest lexicographical point.
int imin = 0 ;
for ( size_t i = 1 ; i < poly . points . size ( ) ; + + i ) {
const Point & pmin = poly . points [ imin ] ;
const Point & p = poly . points [ i ] ;
if ( p . x < pmin . x | | ( p . x = = pmin . x & & p . y < pmin . y ) )
imin = i ;
}
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// 2) Detect the orientation of the corner imin.
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size_t iPrev = ( ( imin = = 0 ) ? poly . points . size ( ) : imin ) - 1 ;
size_t iNext = ( ( imin + 1 = = poly . points . size ( ) ) ? 0 : imin + 1 ) ;
Orientation o = orient ( poly . points [ iPrev ] , poly . points [ imin ] , poly . points [ iNext ] ) ;
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// The lowest bottom point must not be collinear if the polygon does not contain duplicate points
// or overlapping segments.
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assert ( o ! = ORIENTATION_COLINEAR ) ;
return o = = ORIENTATION_CCW ;
}
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// Having a segment of a closed polygon, calculate its Euclidian length.
// The segment indices seg1 and seg2 signify an end point of an edge in the forward direction of the loop,
// therefore the point p1 lies on poly.points[seg1-1], poly.points[seg1] etc.
static inline coordf_t segment_length ( const Polygon & poly , size_t seg1 , const Point & p1 , size_t seg2 , const Point & p2 )
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{
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# ifdef SLIC3R_DEBUG
// Verify that p1 lies on seg1. This is difficult to verify precisely,
// but at least verify, that p1 lies in the bounding box of seg1.
for ( size_t i = 0 ; i < 2 ; + + i ) {
size_t seg = ( i = = 0 ) ? seg1 : seg2 ;
Point px = ( i = = 0 ) ? p1 : p2 ;
Point pa = poly . points [ ( ( seg = = 0 ) ? poly . points . size ( ) : seg ) - 1 ] ;
Point pb = poly . points [ seg ] ;
if ( pa . x > pb . x )
std : : swap ( pa . x , pb . x ) ;
if ( pa . y > pb . y )
std : : swap ( pa . y , pb . y ) ;
assert ( px . x > = pa . x & & px . x < = pb . x ) ;
assert ( px . y > = pa . y & & px . y < = pb . y ) ;
}
# endif /* SLIC3R_DEBUG */
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const Point * pPrev = & p1 ;
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const Point * pThis = NULL ;
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coordf_t len = 0 ;
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if ( seg1 < = seg2 ) {
for ( size_t i = seg1 ; i < seg2 ; + + i , pPrev = pThis )
len + = pPrev - > distance_to ( * ( pThis = & poly . points [ i ] ) ) ;
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} else {
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for ( size_t i = seg1 ; i < poly . points . size ( ) ; + + i , pPrev = pThis )
len + = pPrev - > distance_to ( * ( pThis = & poly . points [ i ] ) ) ;
for ( size_t i = 0 ; i < seg2 ; + + i , pPrev = pThis )
len + = pPrev - > distance_to ( * ( pThis = & poly . points [ i ] ) ) ;
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}
len + = pPrev - > distance_to ( p2 ) ;
return len ;
}
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// Append a segment of a closed polygon to a polyline.
// The segment indices seg1 and seg2 signify an end point of an edge in the forward direction of the loop.
// Only insert intermediate points between seg1 and seg2.
static inline void polygon_segment_append ( Points & out , const Polygon & polygon , size_t seg1 , size_t seg2 )
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{
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if ( seg1 = = seg2 ) {
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// Nothing to append from this segment.
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} else if ( seg1 < seg2 ) {
// Do not append a point pointed to by seg2.
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out . insert ( out . end ( ) , polygon . points . begin ( ) + seg1 , polygon . points . begin ( ) + seg2 ) ;
} else {
out . reserve ( out . size ( ) + seg2 + polygon . points . size ( ) - seg1 ) ;
out . insert ( out . end ( ) , polygon . points . begin ( ) + seg1 , polygon . points . end ( ) ) ;
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// Do not append a point pointed to by seg2.
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out . insert ( out . end ( ) , polygon . points . begin ( ) , polygon . points . begin ( ) + seg2 ) ;
}
}
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// Append a segment of a closed polygon to a polyline.
// The segment indices seg1 and seg2 signify an end point of an edge in the forward direction of the loop,
// but this time the segment is traversed backward.
// Only insert intermediate points between seg1 and seg2.
static inline void polygon_segment_append_reversed ( Points & out , const Polygon & polygon , size_t seg1 , size_t seg2 )
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{
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if ( seg1 > = seg2 ) {
out . reserve ( seg1 - seg2 ) ;
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for ( size_t i = seg1 ; i > seg2 ; - - i )
out . push_back ( polygon . points [ i - 1 ] ) ;
} else {
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// it could be, that seg1 == seg2. In that case, append the complete loop.
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out . reserve ( out . size ( ) + seg2 + polygon . points . size ( ) - seg1 ) ;
for ( size_t i = seg1 ; i > 0 ; - - i )
out . push_back ( polygon . points [ i - 1 ] ) ;
for ( size_t i = polygon . points . size ( ) ; i > seg2 ; - - i )
out . push_back ( polygon . points [ i - 1 ] ) ;
}
}
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// Intersection point of a vertical line with a polygon segment.
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class SegmentIntersection
{
public :
SegmentIntersection ( ) :
iContour ( 0 ) ,
iSegment ( 0 ) ,
pos ( 0 ) ,
type ( UNKNOWN ) ,
consumed_vertical_up ( false ) ,
consumed_perimeter_right ( false )
{ }
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// Index of a contour in ExPolygonWithOffset, with which this vertical line intersects.
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size_t iContour ;
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// Index of a segment in iContour, with which this vertical line intersects.
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size_t iSegment ;
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// y position of the intersection.
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coord_t pos ;
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// Kind of intersection. With the original contour, or with the inner offestted contour?
// A vertical segment will be at least intersected by OUTER_LOW, OUTER_HIGH,
// but it could be intersected with OUTER_LOW, INNER_LOW, INNER_HIGH, OUTER_HIGH,
// and there may be more than one pair of INNER_LOW, INNER_HIGH between OUTER_LOW, OUTER_HIGH.
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enum SegmentIntersectionType {
OUTER_LOW = 0 ,
OUTER_HIGH = 1 ,
INNER_LOW = 2 ,
INNER_HIGH = 3 ,
UNKNOWN = - 1
} ;
SegmentIntersectionType type ;
// Was this segment along the y axis consumed?
// Up means up along the vertical segment.
bool consumed_vertical_up ;
// Was a segment of the inner perimeter contour consumed?
// Right means right from the vertical segment.
bool consumed_perimeter_right ;
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// For the INNER_LOW type, this point may be connected to another INNER_LOW point following a perimeter contour.
// For the INNER_HIGH type, this point may be connected to another INNER_HIGH point following a perimeter contour.
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// If INNER_LOW is connected to INNER_HIGH or vice versa,
// one has to make sure the vertical infill line does not overlap with the connecting perimeter line.
bool is_inner ( ) const { return type = = INNER_LOW | | type = = INNER_HIGH ; }
bool is_outer ( ) const { return type = = OUTER_LOW | | type = = OUTER_HIGH ; }
bool is_low ( ) const { return type = = INNER_LOW | | type = = OUTER_LOW ; }
bool is_high ( ) const { return type = = INNER_HIGH | | type = = OUTER_HIGH ; }
bool operator < ( const SegmentIntersection & other ) const
{ return pos < other . pos ; }
} ;
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// A vertical line with intersection points with polygons.
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class SegmentedIntersectionLine
{
public :
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// Index of this vertical intersection line.
size_t idx ;
// x position of this vertical intersection line.
coord_t pos ;
// List of intersection points with polygons, sorted increasingly by the y axis.
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std : : vector < SegmentIntersection > intersections ;
} ;
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// A container maintaining an expolygon with its inner offsetted polygon.
// The purpose of the inner offsetted polygon is to provide segments to connect the infill lines.
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struct ExPolygonWithOffset
{
public :
ExPolygonWithOffset ( const ExPolygon & aexpolygon , coord_t aoffset ) : expolygon ( aexpolygon )
{
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polygons_inner = offset ( ( Polygons ) expolygon , aoffset ,
CLIPPER_OFFSET_SCALE ,
ClipperLib : : jtMiter ,
// for the infill pattern, don't cut the corners.
// default miterLimt = 3
10. ) ;
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n_contours_outer = 1 + expolygon . holes . size ( ) ;
n_contours_inner = polygons_inner . size ( ) ;
n_contours = n_contours_outer + n_contours_inner ;
polygons_inner_ccw . assign ( polygons_inner . size ( ) , false ) ;
for ( size_t i = 0 ; i < polygons_inner . size ( ) ; + + i )
polygons_inner_ccw [ i ] = is_ccw ( polygons_inner [ i ] ) ;
# ifdef SLIC3R_DEBUG
// Verify orientation of the expolygon.
assert ( is_ccw ( expolygon . contour ) ) ;
for ( size_t i = 0 ; i < expolygon . holes . size ( ) ; + + i )
assert ( is_ccw ( expolygon . holes [ i ] ) ) ;
# endif /* SLIC3R_DEBUG */
}
// Outer contour of the expolygon.
bool is_contour_external ( size_t idx ) const { return idx = = 0 ; }
// Any contour of the expolygon.
bool is_contour_outer ( size_t idx ) const { return idx < n_contours_inner ; }
// Contour of the shrunk expolygon.
bool is_contour_inner ( size_t idx ) const { return idx > = n_contours_inner ; }
const Polygon & contour ( size_t idx ) const {
return is_contour_external ( idx ) ? expolygon . contour :
( is_contour_outer ( idx ) ? expolygon . holes [ idx - 1 ] : polygons_inner [ idx - n_contours_inner ] ) ;
}
bool is_contour_ccw ( size_t idx ) const {
return is_contour_external ( idx ) | | ( is_contour_inner ( idx ) & & polygons_inner_ccw [ idx - n_contours_inner ] ) ;
}
const ExPolygon & expolygon ;
Polygons polygons_inner ;
size_t n_contours_outer ;
size_t n_contours_inner ;
size_t n_contours ;
protected :
// For each polygon of polygons_inner, remember its orientation.
std : : vector < unsigned char > polygons_inner_ccw ;
} ;
// For a vertical line, an inner contour and an intersection point,
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// find an intersection point on the previous resp. next vertical line.
// The intersection point is connected with the prev resp. next intersection point with iInnerContour.
// Return -1 if there is no such point on the previous resp. next vertical line.
static inline int intersection_on_prev_next_vertical_line (
const ExPolygonWithOffset & poly_with_offset ,
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const std : : vector < SegmentedIntersectionLine > & segs ,
size_t iVerticalLine ,
size_t iInnerContour ,
size_t iIntersection ,
bool dir_is_next )
{
size_t iVerticalLineOther = iVerticalLine ;
if ( dir_is_next ) {
if ( + + iVerticalLineOther = = segs . size ( ) )
// No successive vertical line.
return - 1 ;
} else if ( iVerticalLineOther - - = = 0 ) {
// No preceding vertical line.
return - 1 ;
}
const SegmentedIntersectionLine & il = segs [ iVerticalLine ] ;
const SegmentIntersection & itsct = il . intersections [ iIntersection ] ;
const SegmentedIntersectionLine & il2 = segs [ iVerticalLineOther ] ;
const Polygon & poly = poly_with_offset . contour ( iInnerContour ) ;
const bool ccw = poly_with_offset . is_contour_ccw ( iInnerContour ) ;
// Resulting index of an intersection point on il2.
int out = - 1 ;
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// Find an intersection point on iVerticalLineOther, intersecting iInnerContour
// at the same orientation as iIntersection, and being closest to iIntersection
// in the number of contour segments, when following the direction of the contour.
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int dmin = std : : numeric_limits < int > : : max ( ) ;
for ( size_t i = 0 ; i < il2 . intersections . size ( ) ; + + i ) {
const SegmentIntersection & itsct2 = il2 . intersections [ i ] ;
if ( itsct . iContour = = itsct2 . iContour & & itsct . type = = itsct2 . type ) {
// The intersection points lie on the same contour and have the same orientation.
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// Find the intersection point with a shortest path in the direction of the contour.
int d = int ( itsct2 . iSegment ) - int ( itsct . iSegment ) ;
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if ( ccw ! = dir_is_next )
d = - d ;
if ( d < 0 )
d + = int ( poly . points . size ( ) ) ;
if ( d < dmin ) {
out = i ;
dmin = d ;
}
}
}
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//FIXME this routine is not asymptotic optimal, it will be slow if there are many intersection points along the line.
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return out ;
}
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static inline int intersection_on_prev_vertical_line (
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const ExPolygonWithOffset & poly_with_offset ,
const std : : vector < SegmentedIntersectionLine > & segs ,
size_t iVerticalLine ,
size_t iInnerContour ,
size_t iIntersection )
{
return intersection_on_prev_next_vertical_line ( poly_with_offset , segs , iVerticalLine , iInnerContour , iIntersection , false ) ;
}
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static inline intersection_on_next_vertical_line (
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const ExPolygonWithOffset & poly_with_offset ,
const std : : vector < SegmentedIntersectionLine > & segs ,
size_t iVerticalLine ,
size_t iInnerContour ,
size_t iIntersection )
{
return intersection_on_prev_next_vertical_line ( poly_with_offset , segs , iVerticalLine , iInnerContour , iIntersection , true ) ;
}
// Find an intersection on a previous line, but return -1, if the connecting segment of a perimeter was already extruded.
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static inline int intersection_unused_on_prev_next_vertical_line (
const ExPolygonWithOffset & poly_with_offset ,
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const std : : vector < SegmentedIntersectionLine > & segs ,
size_t iVerticalLine ,
size_t iInnerContour ,
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size_t iIntersection ,
bool dir_is_next )
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{
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int iIntersectionOther = intersection_on_prev_next_vertical_line ( poly_with_offset , segs , iVerticalLine , iInnerContour , iIntersection , dir_is_next ) ;
if ( iIntersectionOther = = - 1 )
return - 1 ;
//FIXME this routine will propose a connecting line even if the connecting perimeter segment intersects iVertical line multiple times before reaching iIntersectionOther.
assert ( dir_is_next ? ( iVerticalLine + 1 < segs . size ( ) ) : ( iVerticalLine > 0 ) ) ;
const SegmentedIntersectionLine & il_this = segs [ iVerticalLine ] ;
const SegmentIntersection & itsct_this = il_this . intersections [ iIntersection ] ;
const SegmentedIntersectionLine & il_other = segs [ dir_is_next ? ( iVerticalLine + 1 ) : ( iVerticalLine - 1 ) ] ;
const SegmentIntersection & itsct_other = il_other . intersections [ iIntersectionOther ] ;
assert ( itsct_other . is_inner ( ) ) ;
assert ( itsct_other . is_low ( ) | | iIntersectionOther > 1 ) ;
if ( dir_is_next ? itsct_this . consumed_perimeter_right : itsct_other . consumed_perimeter_right )
// This perimeter segment was already consumed.
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return - 1 ;
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if ( itsct_other . is_low ( ) ? itsct_other . consumed_vertical_up : il_other . intersections [ iIntersectionOther - 1 ] . consumed_vertical_up )
// This vertical segment was already consumed.
return - 1 ;
return iIntersectionOther ;
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}
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static inline intersection_unused_on_prev_vertical_line (
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const ExPolygonWithOffset & poly_with_offset ,
const std : : vector < SegmentedIntersectionLine > & segs ,
size_t iVerticalLine ,
size_t iInnerContour ,
size_t iIntersection )
{
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return intersection_unused_on_prev_next_vertical_line ( poly_with_offset , segs , iVerticalLine , iInnerContour , iIntersection , false ) ;
}
static inline intersection_unused_on_next_vertical_line (
const ExPolygonWithOffset & poly_with_offset ,
const std : : vector < SegmentedIntersectionLine > & segs ,
size_t iVerticalLine ,
size_t iInnerContour ,
size_t iIntersection )
{
return intersection_unused_on_prev_next_vertical_line ( poly_with_offset , segs , iVerticalLine , iInnerContour , iIntersection , true ) ;
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}
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// Measure an Euclidian length of a perimeter segment when going from iIntersection to iIntersection2.
static inline coordf_t measure_perimeter_prev_next_segment_length (
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const ExPolygonWithOffset & poly_with_offset ,
const std : : vector < SegmentedIntersectionLine > & segs ,
size_t iVerticalLine ,
size_t iInnerContour ,
size_t iIntersection ,
size_t iIntersection2 ,
bool dir_is_next )
{
size_t iVerticalLineOther = iVerticalLine ;
if ( dir_is_next ) {
if ( + + iVerticalLineOther = = segs . size ( ) )
// No successive vertical line.
return coordf_t ( - 1 ) ;
} else if ( iVerticalLineOther - - = = 0 ) {
// No preceding vertical line.
return coordf_t ( - 1 ) ;
}
const SegmentedIntersectionLine & il = segs [ iVerticalLine ] ;
const SegmentIntersection & itsct = il . intersections [ iIntersection ] ;
const SegmentedIntersectionLine & il2 = segs [ iVerticalLineOther ] ;
const SegmentIntersection & itsct2 = il2 . intersections [ iIntersection2 ] ;
const Polygon & poly = poly_with_offset . contour ( iInnerContour ) ;
const bool ccw = poly_with_offset . is_contour_ccw ( iInnerContour ) ;
assert ( itsct . type = = itsct2 . type ) ;
assert ( itsct . iContour = = itsct2 . iContour ) ;
assert ( itsct . is_inner ( ) ) ;
const bool forward = ( itsct . is_low ( ) = = ccw ) = = dir_is_next ;
Point p1 ( il . pos , itsct . pos ) ;
Point p2 ( il2 . pos , itsct2 . pos ) ;
return forward ?
segment_length ( poly , itsct . iSegment , p1 , itsct2 . iSegment , p2 ) :
segment_length ( poly , itsct2 . iSegment , p2 , itsct . iSegment , p1 ) ;
}
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static inline coordf_t measure_perimeter_prev_segment_length (
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const ExPolygonWithOffset & poly_with_offset ,
const std : : vector < SegmentedIntersectionLine > & segs ,
size_t iVerticalLine ,
size_t iInnerContour ,
size_t iIntersection ,
size_t iIntersection2 )
{
return measure_perimeter_prev_next_segment_length ( poly_with_offset , segs , iVerticalLine , iInnerContour , iIntersection , iIntersection2 , false ) ;
}
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static inline coordf_t measure_perimeter_next_segment_length (
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const ExPolygonWithOffset & poly_with_offset ,
const std : : vector < SegmentedIntersectionLine > & segs ,
size_t iVerticalLine ,
size_t iInnerContour ,
size_t iIntersection ,
size_t iIntersection2 )
{
return measure_perimeter_prev_next_segment_length ( poly_with_offset , segs , iVerticalLine , iInnerContour , iIntersection , iIntersection2 , true ) ;
}
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// Append the points of a perimeter segment when going from iIntersection to iIntersection2.
// The first point (the point of iIntersection) will not be inserted,
// the last point will be inserted.
static inline void emit_perimeter_prev_next_segment (
const ExPolygonWithOffset & poly_with_offset ,
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const std : : vector < SegmentedIntersectionLine > & segs ,
size_t iVerticalLine ,
size_t iInnerContour ,
size_t iIntersection ,
size_t iIntersection2 ,
Polyline & out ,
bool dir_is_next )
{
size_t iVerticalLineOther = iVerticalLine ;
if ( dir_is_next ) {
+ + iVerticalLineOther ;
assert ( iVerticalLineOther < segs . size ( ) ) ;
} else {
assert ( iVerticalLineOther > 0 ) ;
- - iVerticalLineOther ;
}
const SegmentedIntersectionLine & il = segs [ iVerticalLine ] ;
const SegmentIntersection & itsct = il . intersections [ iIntersection ] ;
const SegmentedIntersectionLine & il2 = segs [ iVerticalLineOther ] ;
const SegmentIntersection & itsct2 = il2 . intersections [ iIntersection2 ] ;
const Polygon & poly = poly_with_offset . contour ( iInnerContour ) ;
const bool ccw = poly_with_offset . is_contour_ccw ( iInnerContour ) ;
assert ( itsct . type = = itsct2 . type ) ;
assert ( itsct . iContour = = itsct2 . iContour ) ;
assert ( itsct . is_inner ( ) ) ;
const bool forward = ( itsct . is_low ( ) = = ccw ) = = dir_is_next ;
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// Do not append the first point.
// out.points.push_back(Point(il.pos, itsct.pos));
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if ( forward )
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polygon_segment_append ( out . points , poly , itsct . iSegment , itsct2 . iSegment ) ;
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else
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polygon_segment_append_reversed ( out . points , poly , itsct . iSegment , itsct2 . iSegment ) ;
// Append the last point.
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out . points . push_back ( Point ( il2 . pos , itsct2 . pos ) ) ;
}
Polylines FillRectilinear2 : : fill_surface ( const Surface * surface , const FillParams & params )
{
// rotate polygons so that we can work with vertical lines here
ExPolygon expolygon = surface - > expolygon ;
std : : pair < float , Point > rotate_vector = this - > infill_direction ( surface ) ;
expolygon . rotate ( - rotate_vector . first ) ;
// No need to translate the polygon anyhow for the infill.
// The infill will be performed inside a bounding box of the expolygon and its absolute position does not matter.
// expolygon.translate(rotate_vector.second.x, rotate_vector.second.y);
this - > _min_spacing = scale_ ( this - > spacing ) ;
assert ( params . density > 0.0001f & & params . density < = 1.f ) ;
this - > _line_spacing = coord_t ( coordf_t ( this - > _min_spacing ) / params . density ) ;
this - > _diagonal_distance = this - > _line_spacing * 2 ;
BoundingBox bounding_box = expolygon . contour . bounding_box ( ) ;
// define flow spacing according to requested density
if ( params . density > 0.9999f & & ! params . dont_adjust ) {
this - > _line_spacing = this - > adjust_solid_spacing ( bounding_box . size ( ) . x , this - > _line_spacing ) ;
this - > spacing = unscale ( this - > _line_spacing ) ;
} else {
// extend bounding box so that our pattern will be aligned with other layers
bounding_box . merge ( Point (
bounding_box . min . x - ( bounding_box . min . x % this - > _line_spacing ) ,
bounding_box . min . y - ( bounding_box . min . y % this - > _line_spacing ) ) ) ;
}
// Intersect a set of euqally spaced vertical lines wiht expolygon.
size_t n_vlines = ( bounding_box . max . x - bounding_box . min . x + SCALED_EPSILON ) / this - > _line_spacing ;
coord_t x0 = bounding_box . min . x + this - > _line_spacing ;
// On these polygons the infill lines will be connected.
ExPolygonWithOffset poly_with_offset ( expolygon , - _min_spacing / 2 ) ;
# ifdef SLIC3R_DEBUG
char path [ 2048 ] ;
static int iRun = 0 ;
sprintf ( path , " out/FillRectilinear2-%d.svg " , iRun ) ;
BoundingBox bbox_svg = expolygon . contour . bounding_box ( ) ;
bbox_svg . min . x - = coord_t ( 1. / SCALING_FACTOR ) ;
bbox_svg . min . y - = coord_t ( 1. / SCALING_FACTOR ) ;
bbox_svg . max . x + = coord_t ( 1. / SCALING_FACTOR ) ;
bbox_svg . max . y + = coord_t ( 1. / SCALING_FACTOR ) ;
: : Slic3r : : SVG svg ( path , bbox_svg ) ;
svg . draw ( expolygon . lines ( ) ) ;
svg . draw ( poly_with_offset . polygons_inner ) ;
{
char path2 [ 2048 ] ;
sprintf ( path2 , " out/FillRectilinear2-initial-%d.svg " , iRun ) ;
: : Slic3r : : SVG svg ( path2 , bbox_svg ) ;
svg . draw ( expolygon . lines ( ) ) ;
svg . draw ( poly_with_offset . polygons_inner ) ;
svg . Close ( ) ;
}
iRun + + ;
# endif /* SLIC3R_DEBUG */
// For each contour
// Allocate the storage for the segments.
std : : vector < SegmentedIntersectionLine > segs ( n_vlines , SegmentedIntersectionLine ( ) ) ;
for ( size_t i = 0 ; i < n_vlines ; + + i ) {
segs [ i ] . idx = i ;
segs [ i ] . pos = x0 + i * this - > _line_spacing ;
}
for ( size_t iContour = 0 ; iContour < poly_with_offset . n_contours ; + + iContour ) {
const Points & contour = poly_with_offset . contour ( iContour ) ;
if ( contour . size ( ) < 2 )
continue ;
// For each segment
for ( size_t iSegment = 0 ; iSegment < contour . size ( ) ; + + iSegment ) {
size_t iPrev = ( ( iSegment = = 0 ) ? contour . size ( ) : iSegment ) - 1 ;
const Point & p1 = contour [ iPrev ] ;
const Point & p2 = contour [ iSegment ] ;
// Which of the equally spaced vertical lines is intersected by this segment?
coord_t l = p1 . x ;
coord_t r = p2 . x ;
if ( l > r )
std : : swap ( l , r ) ;
// il, ir are the left / right indices of vertical lines intersecting a segment
int il = ( l - x0 ) / this - > _line_spacing ;
while ( il * this - > _line_spacing + x0 < l )
+ + il ;
il = std : : max ( int ( 0 ) , il ) ;
int ir = ( r - x0 + this - > _line_spacing ) / this - > _line_spacing ;
while ( ir * this - > _line_spacing + x0 > r )
- - ir ;
ir = std : : min ( int ( segs . size ( ) ) - 1 , ir ) ;
if ( il > ir )
// No vertical line intersects this segment.
continue ;
assert ( il > = 0 & & il < segs . size ( ) ) ;
assert ( ir > = 0 & & ir < segs . size ( ) ) ;
if ( l = = r ) {
// The segment is vertical.
SegmentIntersection is ;
is . iContour = iContour ;
is . iSegment = iSegment ;
is . pos = p1 . y ;
segs [ il ] . intersections . push_back ( is ) ;
is . pos = p2 . y ;
segs [ il ] . intersections . push_back ( is ) ;
continue ;
}
for ( int i = il ; i < = ir ; + + i ) {
SegmentIntersection is ;
is . iContour = iContour ;
is . iSegment = iSegment ;
assert ( l < = segs [ i ] . pos ) ;
assert ( r > = segs [ i ] . pos ) ;
// Calculate the intersection position in y axis. x is known.
double t = double ( segs [ i ] . pos - p1 . x ) / double ( p2 . x - p1 . x ) ;
assert ( t > - 0.000001 & & t < 1.000001 ) ;
t = clamp ( 0. , 1. , t ) ;
coord_t lo = p1 . y ;
coord_t hi = p2 . y ;
if ( lo > hi )
std : : swap ( lo , hi ) ;
is . pos = p1 . y + coord_t ( t * double ( p2 . y - p1 . y ) ) ;
assert ( is . pos > lo - 0.000001 & & is . pos < hi + 0.000001 ) ;
is . pos = clamp ( lo , hi , is . pos ) ;
segs [ i ] . intersections . push_back ( is ) ;
}
}
}
// Sort the intersections along their segments, specify the intersection types.
for ( size_t i_seg = 0 ; i_seg < segs . size ( ) ; + + i_seg ) {
SegmentedIntersectionLine & sil = segs [ i_seg ] ;
// Sort the intersection points. This needs to be verified, because the intersection points were calculated
// using imprecise arithmetics.
std : : sort ( sil . intersections . begin ( ) , sil . intersections . end ( ) ) ;
// Verify the order, bubble sort the intersections until sorted.
bool modified = false ;
do {
modified = false ;
for ( size_t i = 1 ; i < sil . intersections . size ( ) ; + + i ) {
size_t iContour1 = sil . intersections [ i - 1 ] . iContour ;
size_t iContour2 = sil . intersections [ i ] . iContour ;
const Points & contour1 = poly_with_offset . contour ( iContour1 ) ;
const Points & contour2 = poly_with_offset . contour ( iContour2 ) ;
size_t iSegment1 = sil . intersections [ i - 1 ] . iSegment ;
size_t iPrev1 = ( ( iSegment1 = = 0 ) ? contour1 . size ( ) : iSegment1 ) - 1 ;
size_t iSegment2 = sil . intersections [ i ] . iSegment ;
size_t iPrev2 = ( ( iSegment2 = = 0 ) ? contour2 . size ( ) : iSegment2 ) - 1 ;
bool swap = false ;
if ( iContour1 = = iContour2 & & iSegment1 = = iSegment2 ) {
// The same segment, it has to be vertical.
assert ( iPrev1 = = iPrev2 ) ;
swap = contour1 [ iPrev1 ] . y > contour1 [ iContour1 ] . y ;
# ifdef SLIC3R_DEBUG
if ( swap )
printf ( " Swapping when single vertical segment \n " ) ;
# endif
} else {
// Segments are in a general position. Here an exact airthmetics may come into play.
coord_t y1max = std : : max ( contour1 [ iPrev1 ] . y , contour1 [ iSegment1 ] . y ) ;
coord_t y2min = std : : min ( contour2 [ iPrev2 ] . y , contour2 [ iSegment2 ] . y ) ;
if ( y1max < y2min ) {
// The segments are separated, nothing to do.
} else {
// Use an exact predicate to verify, that segment1 is below segment2.
const Point * a = & contour1 [ iPrev1 ] ;
const Point * b = & contour1 [ iSegment1 ] ;
const Point * c = & contour2 [ iPrev2 ] ;
const Point * d = & contour2 [ iSegment2 ] ;
# ifdef SLIC3R_DEBUG
const Point x1 ( sil . pos , sil . intersections [ i - 1 ] . pos ) ;
const Point x2 ( sil . pos , sil . intersections [ i ] . pos ) ;
bool successive = false ;
# endif /* SLIC3R_DEBUG */
if ( a - > x > b - > x )
std : : swap ( a , b ) ;
if ( c - > x > d - > x )
std : : swap ( c , d ) ;
bool upper_more_left = false ;
if ( a - > x > c - > x ) {
upper_more_left = true ;
std : : swap ( a , c ) ;
std : : swap ( b , d ) ;
}
if ( a = = c | | b = = c ) {
assert ( iContour1 = = iContour2 ) ;
assert ( iSegment1 = = iPrev2 | | iPrev1 = = iSegment2 ) ;
std : : swap ( c , d ) ;
assert ( a ! = c & & b ! = c ) ;
# ifdef SLIC3R_DEBUG
successive = true ;
# endif /* SLIC3R_DEBUG */
}
Orientation o = orient ( * a , * b , * c ) ;
assert ( ! ORIENTATION_COLINEAR ) ;
swap = upper_more_left ! = ( o = = ORIENTATION_CW ) ;
# ifdef SLIC3R_DEBUG
if ( swap )
printf ( successive ?
" Swapping when iContour1 == iContour2 and successive segments \n " :
" Swapping when exact predicate \n " ) ;
# endif
}
}
if ( swap ) {
// Swap the intersection points, but keep the original positions, so they are sorted.
std : : swap ( sil . intersections [ i - 1 ] , sil . intersections [ i ] ) ;
std : : swap ( sil . intersections [ i - 1 ] . pos , sil . intersections [ i ] . pos ) ;
modified = true ;
}
}
} while ( modified ) ;
// Assign the intersection types.
for ( size_t i = 0 ; i < sil . intersections . size ( ) ; + + i ) {
// What is the orientation of the segment at the intersection point?
size_t iContour = sil . intersections [ i ] . iContour ;
const Points & contour = poly_with_offset . contour ( iContour ) ;
size_t iSegment = sil . intersections [ i ] . iSegment ;
size_t iPrev = ( ( iSegment = = 0 ) ? contour . size ( ) : iSegment ) - 1 ;
coord_t dir = contour [ iSegment ] . x - contour [ iPrev ] . x ;
bool ccw = poly_with_offset . is_contour_ccw ( iContour ) ;
bool low = ( dir > 0 ) = = ccw ;
sil . intersections [ i ] . type = poly_with_offset . is_contour_outer ( iContour ) ?
( low ? SegmentIntersection : : OUTER_LOW : SegmentIntersection : : OUTER_HIGH ) :
( low ? SegmentIntersection : : INNER_LOW : SegmentIntersection : : INNER_HIGH ) ;
}
}
# ifdef SLIC3R_DEBUG
// Verify the segments & paint them.
for ( size_t i_seg = 0 ; i_seg < segs . size ( ) ; + + i_seg ) {
SegmentedIntersectionLine & sil = segs [ i_seg ] ;
// The intersection points have to be even.
assert ( ( sil . intersections . size ( ) & 1 ) = = 0 ) ;
for ( size_t i = 0 ; i < sil . intersections . size ( ) ; ) {
// An intersection segment crossing the bigger contour may cross the inner offsetted contour even number of times.
assert ( sil . intersections [ i ] . type = = SegmentIntersection : : OUTER_LOW ) ;
size_t j = i + 1 ;
assert ( j < sil . intersections . size ( ) ) ;
assert ( sil . intersections [ j ] . type = = SegmentIntersection : : INNER_LOW | | sil . intersections [ j ] . type = = SegmentIntersection : : OUTER_HIGH ) ;
for ( ; j < sil . intersections . size ( ) & & sil . intersections [ j ] . is_inner ( ) ; + + j ) ;
assert ( j < sil . intersections . size ( ) ) ;
assert ( ( j & 1 ) = = 1 ) ;
assert ( sil . intersections [ j ] . type = = SegmentIntersection : : OUTER_HIGH ) ;
assert ( i + 1 = = j | | sil . intersections [ j - 1 ] . type = = SegmentIntersection : : INNER_HIGH ) ;
if ( i + 1 = = j ) {
svg . draw ( Line ( Point ( sil . pos , sil . intersections [ i ] . pos ) , Point ( sil . pos , sil . intersections [ j ] . pos ) ) , " blue " ) ;
} else {
svg . draw ( Line ( Point ( sil . pos , sil . intersections [ i ] . pos ) , Point ( sil . pos , sil . intersections [ i + 1 ] . pos ) ) , " green " ) ;
svg . draw ( Line ( Point ( sil . pos , sil . intersections [ i + 1 ] . pos ) , Point ( sil . pos , sil . intersections [ j - 1 ] . pos ) ) , ( j - i + 1 > 4 ) ? " yellow " : " magenta " ) ;
svg . draw ( Line ( Point ( sil . pos , sil . intersections [ j - 1 ] . pos ) , Point ( sil . pos , sil . intersections [ j ] . pos ) ) , " green " ) ;
}
i = j + 1 ;
}
}
svg . Close ( ) ;
# endif /* SLIC3R_DEBUG */
// Now construct a graph.
// Find the first point.
//FIXME ideally one would plan the initial point to be closest to the current print head position.
size_t i_vline = 0 ;
size_t i_intersection = size_t ( - 1 ) ;
// Follow the line, connect the lines into a graph.
// Until no new line could be added to the output path:
Point pointLast ;
Polylines polylines_out ;
Polyline * polyline_current = NULL ;
for ( ; ; ) {
if ( i_intersection = = size_t ( - 1 ) ) {
// The path has been interrupted. Find a next starting point, closest to the previous extruder position.
coordf_t dist2min = std : : numeric_limits < coordf_t > ( ) . max ( ) ;
for ( size_t i_vline2 = 0 ; i_vline2 < segs . size ( ) ; + + i_vline2 ) {
const SegmentedIntersectionLine & seg = segs [ i_vline2 ] ;
if ( ! seg . intersections . empty ( ) ) {
assert ( seg . intersections . size ( ) > 1 ) ;
// Even number of intersections with the loops.
assert ( ( seg . intersections . size ( ) & 1 ) = = 0 ) ;
assert ( seg . intersections . front ( ) . type = = SegmentIntersection : : OUTER_LOW ) ;
for ( size_t i = 0 ; i < seg . intersections . size ( ) ; + + i ) {
const SegmentIntersection & intrsctn = seg . intersections [ i ] ;
if ( intrsctn . is_outer ( ) ) {
assert ( intrsctn . is_low ( ) | | i > 0 ) ;
bool consumed = intrsctn . is_low ( ) ?
intrsctn . consumed_vertical_up :
seg . intersections [ i - 1 ] . consumed_vertical_up ;
if ( ! consumed ) {
coordf_t dist2 = sqr ( coordf_t ( pointLast . x - seg . pos ) ) + sqr ( coordf_t ( pointLast . y - intrsctn . pos ) ) ;
if ( dist2 < dist2min ) {
dist2min = dist2 ;
i_vline = i_vline2 ;
i_intersection = i ;
if ( polylines_out . empty ( ) ) {
// Initial state, take the first line, which is the first from the left.
goto found ;
}
}
}
}
}
}
}
if ( i_intersection = = size_t ( - 1 ) )
// We are finished.
break ;
found :
// Start a new path.
polylines_out . push_back ( Polyline ( ) ) ;
polyline_current = & polylines_out . back ( ) ;
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// Emit the first point of a path.
pointLast = Point ( segs [ i_vline ] . pos , segs [ i_vline ] . intersections [ i_intersection ] . pos ) ;
polyline_current - > points . push_back ( pointLast ) ;
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}
// From the initial point (i_vline, i_intersection), follow a path.
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SegmentedIntersectionLine & seg = segs [ i_vline ] ;
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SegmentIntersection * intrsctn = & seg . intersections [ i_intersection ] ;
bool going_up = intrsctn - > is_low ( ) ;
bool try_connect = false ;
if ( going_up ) {
assert ( ! intrsctn - > consumed_vertical_up ) ;
assert ( i_intersection + 1 < seg . intersections . size ( ) ) ;
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// Step back to the beginning of the vertical segment to mark it as consumed.
if ( intrsctn - > is_inner ( ) ) {
assert ( i_intersection > 0 ) ;
- - intrsctn ;
- - i_intersection ;
}
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// Consume the complete vertical segment up to the outer contour.
do {
intrsctn - > consumed_vertical_up = true ;
+ + intrsctn ;
+ + i_intersection ;
assert ( i_intersection < seg . intersections . size ( ) ) ;
} while ( intrsctn - > type ! = SegmentIntersection : : OUTER_HIGH ) ;
if ( ( intrsctn - 1 ) - > is_inner ( ) ) {
// Step back.
- - intrsctn ;
- - i_intersection ;
assert ( intrsctn - > type = = SegmentIntersection : : INNER_HIGH ) ;
try_connect = true ;
}
} else {
// Going down.
assert ( intrsctn - > is_high ( ) ) ;
assert ( i_intersection > 0 ) ;
assert ( ! ( intrsctn - 1 ) - > consumed_vertical_up ) ;
// Consume the complete vertical segment up to the outer contour.
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if ( intrsctn - > is_inner ( ) )
intrsctn - > consumed_vertical_up = true ;
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do {
assert ( i_intersection > 0 ) ;
- - intrsctn ;
- - i_intersection ;
intrsctn - > consumed_vertical_up = true ;
} while ( intrsctn - > type ! = SegmentIntersection : : OUTER_LOW ) ;
if ( ( intrsctn + 1 ) - > is_inner ( ) ) {
// Step back.
+ + intrsctn ;
+ + i_intersection ;
assert ( intrsctn - > type = = SegmentIntersection : : INNER_LOW ) ;
try_connect = true ;
}
}
if ( try_connect ) {
// Decide, whether to finish the segment, or whether to follow the perimeter.
int iPrev = intersection_unused_on_prev_vertical_line ( poly_with_offset , segs , i_vline , intrsctn - > iContour , i_intersection ) ;
int iNext = intersection_unused_on_next_vertical_line ( poly_with_offset , segs , i_vline , intrsctn - > iContour , i_intersection ) ;
if ( iPrev ! = - 1 | | iNext ! = - 1 ) {
// Zig zag
coord_t distPrev = ( iPrev = = - 1 ) ? std : : numeric_limits < coord_t > : : max ( ) :
measure_perimeter_prev_segment_length ( poly_with_offset , segs , i_vline , intrsctn - > iContour , i_intersection , iPrev ) ;
coord_t distNext = ( iNext = = - 1 ) ? std : : numeric_limits < coord_t > : : max ( ) :
measure_perimeter_next_segment_length ( poly_with_offset , segs , i_vline , intrsctn - > iContour , i_intersection , iNext ) ;
// Take the shorter path.
bool take_next = ( iPrev ! = - 1 & & iNext ! = - 1 ) ? ( distNext < distPrev ) : distNext ! = - 1 ;
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assert ( intrsctn - > is_inner ( ) ) ;
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polyline_current - > points . push_back ( Point ( seg . pos , intrsctn - > pos ) ) ;
emit_perimeter_prev_next_segment ( poly_with_offset , segs , i_vline , intrsctn - > iContour , i_intersection , take_next ? iNext : iPrev , * polyline_current , take_next ) ;
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// Mark both the left and right connecting segment as consumed, because one cannot go to this intersection point as it has been consumed.
if ( iPrev ! = - 1 )
segs [ i_vline - 1 ] . intersections [ iPrev ] . consumed_perimeter_right = true ;
if ( iNext ! = - 1 )
intrsctn - > consumed_perimeter_right = true ;
//FIXME consume the left / right connecting segments at the other end of this line? Currently it is not critical because a perimeter segment is not followed if the vertical segment at the other side has already been consumed.
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// Advance to the neighbor line.
if ( take_next ) {
+ + i_vline ;
i_intersection = iNext ;
} else {
- - i_vline ;
i_intersection = iPrev ;
}
continue ;
}
// Take the complete line up to the outer contour.
if ( going_up )
+ + intrsctn ;
else
- - intrsctn ;
}
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// Finish the current vertical line,
// reset the current vertical line to pick a new starting point in the next round.
assert ( intrsctn - > is_outer ( ) ) ;
assert ( intrsctn - > is_high ( ) = = going_up ) ;
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pointLast = Point ( seg . pos , intrsctn - > pos ) ;
polyline_current - > points . push_back ( pointLast ) ;
intrsctn = NULL ;
i_intersection = - 1 ;
polyline_current = NULL ;
}
// paths must be rotated back
for ( Polylines : : iterator it = polylines_out . begin ( ) ; it ! = polylines_out . end ( ) ; + + it ) {
// No need to translate, the absolute position is irrelevant.
// it->translate(- rotate_vector.second.x, - rotate_vector.second.y);
it - > rotate ( rotate_vector . first ) ;
}
return polylines_out ;
}
} // namespace Slic3r