vamp-build-and-test: DEPENDENCIES/generic/include/boost/polygon/detail/polygon_arbitrary

annotate DEPENDENCIES/generic/include/boost/polygon/detail/polygon_arbitrary_formation.hpp @ 133:4acb5d8d80b6 tip

Don't fail environmental check if README.md exists (but .txt and no-suffix don't)

author	Chris Cannam
date	Tue, 30 Jul 2019 12:25:44 +0100
parents	c530137014c0
children

rev	line source
Chris@16	1 /*
Chris@16	2 Copyright 2008 Intel Corporation
Chris@16	3
Chris@16	4 Use, modification and distribution are subject to the Boost Software License,
Chris@16	5 Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at
Chris@16	6 http://www.boost.org/LICENSE_1_0.txt).
Chris@16	7 */
Chris@16	8 #ifndef BOOST_POLYGON_POLYGON_ARBITRARY_FORMATION_HPP
Chris@16	9 #define BOOST_POLYGON_POLYGON_ARBITRARY_FORMATION_HPP
Chris@16	10 namespace boost { namespace polygon{
Chris@16	11 template <typename T, typename T2>
Chris@16	12 struct PolyLineArbitraryByConcept {};
Chris@16	13
Chris@16	14 template <typename T>
Chris@16	15 class poly_line_arbitrary_polygon_data;
Chris@16	16 template <typename T>
Chris@16	17 class poly_line_arbitrary_hole_data;
Chris@16	18
Chris@16	19 template <typename Unit>
Chris@16	20 struct scanline_base {
Chris@16	21
Chris@16	22 typedef point_data<Unit> Point;
Chris@16	23 typedef std::pair<Point, Point> half_edge;
Chris@16	24
Chris@16	25 class less_point : public std::binary_function<Point, Point, bool> {
Chris@16	26 public:
Chris@16	27 inline less_point() {}
Chris@16	28 inline bool operator () (const Point& pt1, const Point& pt2) const {
Chris@16	29 if(pt1.get(HORIZONTAL) < pt2.get(HORIZONTAL)) return true;
Chris@16	30 if(pt1.get(HORIZONTAL) == pt2.get(HORIZONTAL)) {
Chris@16	31 if(pt1.get(VERTICAL) < pt2.get(VERTICAL)) return true;
Chris@16	32 }
Chris@16	33 return false;
Chris@16	34 }
Chris@16	35 };
Chris@16	36
Chris@16	37 static inline bool between(Point pt, Point pt1, Point pt2) {
Chris@16	38 less_point lp;
Chris@16	39 if(lp(pt1, pt2))
Chris@16	40 return lp(pt, pt2) && lp(pt1, pt);
Chris@16	41 return lp(pt, pt1) && lp(pt2, pt);
Chris@16	42 }
Chris@16	43
Chris@16	44 template <typename area_type>
Chris@16	45 static inline Unit compute_intercept(const area_type& dy2,
Chris@16	46 const area_type& dx1,
Chris@16	47 const area_type& dx2) {
Chris@16	48 //intercept = dy2 * dx1 / dx2
Chris@16	49 //return (Unit)(((area_type)dy2 * (area_type)dx1) / (area_type)dx2);
Chris@16	50 area_type dx1_q = dx1 / dx2;
Chris@16	51 area_type dx1_r = dx1 % dx2;
Chris@16	52 return dx1_q * dy2 + (dy2 * dx1_r)/dx2;
Chris@16	53 }
Chris@16	54
Chris@16	55 template <typename area_type>
Chris@16	56 static inline bool equal_slope(area_type dx1, area_type dy1, area_type dx2, area_type dy2) {
Chris@16	57 typedef typename coordinate_traits<Unit>::unsigned_area_type unsigned_product_type;
Chris@16	58 unsigned_product_type cross_1 = (unsigned_product_type)(dx2 < 0 ? -dx2 :dx2) * (unsigned_product_type)(dy1 < 0 ? -dy1 : dy1);
Chris@16	59 unsigned_product_type cross_2 = (unsigned_product_type)(dx1 < 0 ? -dx1 :dx1) * (unsigned_product_type)(dy2 < 0 ? -dy2 : dy2);
Chris@16	60 int dx1_sign = dx1 < 0 ? -1 : 1;
Chris@16	61 int dx2_sign = dx2 < 0 ? -1 : 1;
Chris@16	62 int dy1_sign = dy1 < 0 ? -1 : 1;
Chris@16	63 int dy2_sign = dy2 < 0 ? -1 : 1;
Chris@16	64 int cross_1_sign = dx2_sign * dy1_sign;
Chris@16	65 int cross_2_sign = dx1_sign * dy2_sign;
Chris@16	66 return cross_1 == cross_2 && (cross_1_sign == cross_2_sign \|\| cross_1 == 0);
Chris@16	67 }
Chris@16	68
Chris@16	69 template <typename T>
Chris@16	70 static inline bool equal_slope_hp(const T& dx1, const T& dy1, const T& dx2, const T& dy2) {
Chris@16	71 return dx1 * dy2 == dx2 * dy1;
Chris@16	72 }
Chris@16	73
Chris@16	74 static inline bool equal_slope(const Unit& x, const Unit& y,
Chris@16	75 const Point& pt1, const Point& pt2) {
Chris@16	76 const Point* pts[2] = {&pt1, &pt2};
Chris@16	77 typedef typename coordinate_traits<Unit>::manhattan_area_type at;
Chris@16	78 at dy2 = (at)pts[1]->get(VERTICAL) - (at)y;
Chris@16	79 at dy1 = (at)pts[0]->get(VERTICAL) - (at)y;
Chris@16	80 at dx2 = (at)pts[1]->get(HORIZONTAL) - (at)x;
Chris@16	81 at dx1 = (at)pts[0]->get(HORIZONTAL) - (at)x;
Chris@16	82 return equal_slope(dx1, dy1, dx2, dy2);
Chris@16	83 }
Chris@16	84
Chris@16	85 template <typename area_type>
Chris@16	86 static inline bool less_slope(area_type dx1, area_type dy1, area_type dx2, area_type dy2) {
Chris@16	87 //reflext x and y slopes to right hand side half plane
Chris@16	88 if(dx1 < 0) {
Chris@16	89 dy1 *= -1;
Chris@16	90 dx1 *= -1;
Chris@16	91 } else if(dx1 == 0) {
Chris@16	92 //if the first slope is vertical the first cannot be less
Chris@16	93 return false;
Chris@16	94 }
Chris@16	95 if(dx2 < 0) {
Chris@16	96 dy2 *= -1;
Chris@16	97 dx2 *= -1;
Chris@16	98 } else if(dx2 == 0) {
Chris@16	99 //if the second slope is vertical the first is always less unless it is also vertical, in which case they are equal
Chris@16	100 return dx1 != 0;
Chris@16	101 }
Chris@16	102 typedef typename coordinate_traits<Unit>::unsigned_area_type unsigned_product_type;
Chris@16	103 unsigned_product_type cross_1 = (unsigned_product_type)(dx2 < 0 ? -dx2 :dx2) * (unsigned_product_type)(dy1 < 0 ? -dy1 : dy1);
Chris@16	104 unsigned_product_type cross_2 = (unsigned_product_type)(dx1 < 0 ? -dx1 :dx1) * (unsigned_product_type)(dy2 < 0 ? -dy2 : dy2);
Chris@16	105 int dx1_sign = dx1 < 0 ? -1 : 1;
Chris@16	106 int dx2_sign = dx2 < 0 ? -1 : 1;
Chris@16	107 int dy1_sign = dy1 < 0 ? -1 : 1;
Chris@16	108 int dy2_sign = dy2 < 0 ? -1 : 1;
Chris@16	109 int cross_1_sign = dx2_sign * dy1_sign;
Chris@16	110 int cross_2_sign = dx1_sign * dy2_sign;
Chris@16	111 if(cross_1_sign < cross_2_sign) return true;
Chris@16	112 if(cross_2_sign < cross_1_sign) return false;
Chris@16	113 if(cross_1_sign == -1) return cross_2 < cross_1;
Chris@16	114 return cross_1 < cross_2;
Chris@16	115 }
Chris@16	116
Chris@16	117 static inline bool less_slope(const Unit& x, const Unit& y,
Chris@16	118 const Point& pt1, const Point& pt2) {
Chris@16	119 const Point* pts[2] = {&pt1, &pt2};
Chris@16	120 //compute y value on edge from pt_ to pts[1] at the x value of pts[0]
Chris@16	121 typedef typename coordinate_traits<Unit>::manhattan_area_type at;
Chris@16	122 at dy2 = (at)pts[1]->get(VERTICAL) - (at)y;
Chris@16	123 at dy1 = (at)pts[0]->get(VERTICAL) - (at)y;
Chris@16	124 at dx2 = (at)pts[1]->get(HORIZONTAL) - (at)x;
Chris@16	125 at dx1 = (at)pts[0]->get(HORIZONTAL) - (at)x;
Chris@16	126 return less_slope(dx1, dy1, dx2, dy2);
Chris@16	127 }
Chris@16	128
Chris@16	129 //return -1 below, 0 on and 1 above line
Chris@16	130 static inline int on_above_or_below(Point pt, const half_edge& he) {
Chris@16	131 if(pt == he.first \|\| pt == he.second) return 0;
Chris@16	132 if(equal_slope(pt.get(HORIZONTAL), pt.get(VERTICAL), he.first, he.second)) return 0;
Chris@16	133 bool less_result = less_slope(pt.get(HORIZONTAL), pt.get(VERTICAL), he.first, he.second);
Chris@16	134 int retval = less_result ? -1 : 1;
Chris@16	135 less_point lp;
Chris@16	136 if(lp(he.second, he.first)) retval *= -1;
Chris@16	137 if(!between(pt, he.first, he.second)) retval *= -1;
Chris@16	138 return retval;
Chris@16	139 }
Chris@16	140
Chris@16	141 //returns true is the segment intersects the integer grid square with lower
Chris@16	142 //left corner at point
Chris@16	143 static inline bool intersects_grid(Point pt, const half_edge& he) {
Chris@16	144 if(pt == he.second) return true;
Chris@16	145 if(pt == he.first) return true;
Chris@16	146 rectangle_data<Unit> rect1;
Chris@16	147 set_points(rect1, he.first, he.second);
Chris@16	148 if(contains(rect1, pt, true)) {
Chris@16	149 if(is_vertical(he) \|\| is_horizontal(he)) return true;
Chris@16	150 } else {
Chris@16	151 return false; //can't intersect a grid not within bounding box
Chris@16	152 }
Chris@16	153 Unit x = pt.get(HORIZONTAL);
Chris@16	154 Unit y = pt.get(VERTICAL);
Chris@16	155 if(equal_slope(x, y, he.first, he.second) &&
Chris@16	156 between(pt, he.first, he.second)) return true;
Chris@16	157 Point pt01(pt.get(HORIZONTAL), pt.get(VERTICAL) + 1);
Chris@16	158 Point pt10(pt.get(HORIZONTAL) + 1, pt.get(VERTICAL));
Chris@16	159 Point pt11(pt.get(HORIZONTAL) + 1, pt.get(VERTICAL) + 1);
Chris@16	160 // if(pt01 == he.first) return true;
Chris@16	161 // if(pt10 == he.first) return true;
Chris@16	162 // if(pt11 == he.first) return true;
Chris@16	163 // if(pt01 == he.second) return true;
Chris@16	164 // if(pt10 == he.second) return true;
Chris@16	165 // if(pt11 == he.second) return true;
Chris@16	166 //check non-integer intersections
Chris@16	167 half_edge widget1(pt, pt11);
Chris@16	168 //intersects but not just at pt11
Chris@16	169 if(intersects(widget1, he) && on_above_or_below(pt11, he)) return true;
Chris@16	170 half_edge widget2(pt01, pt10);
Chris@16	171 //intersects but not just at pt01 or 10
Chris@16	172 if(intersects(widget2, he) && on_above_or_below(pt01, he) && on_above_or_below(pt10, he)) return true;
Chris@16	173 return false;
Chris@16	174 }
Chris@16	175
Chris@16	176 static inline Unit evalAtXforYlazy(Unit xIn, Point pt, Point other_pt) {
Chris@16	177 long double
Chris@16	178 evalAtXforYret, evalAtXforYxIn, evalAtXforYx1, evalAtXforYy1, evalAtXforYdx1, evalAtXforYdx,
Chris@16	179 evalAtXforYdy, evalAtXforYx2, evalAtXforYy2, evalAtXforY0;
Chris@16	180 //y = (x - x1)dy/dx + y1
Chris@16	181 //y = (xIn - pt.x)*(other_pt.y-pt.y)/(other_pt.x-pt.x) + pt.y
Chris@16	182 //assert pt.x != other_pt.x
Chris@16	183 if(pt.y() == other_pt.y())
Chris@16	184 return pt.y();
Chris@16	185 evalAtXforYxIn = xIn;
Chris@16	186 evalAtXforYx1 = pt.get(HORIZONTAL);
Chris@16	187 evalAtXforYy1 = pt.get(VERTICAL);
Chris@16	188 evalAtXforYdx1 = evalAtXforYxIn - evalAtXforYx1;
Chris@16	189 evalAtXforY0 = 0;
Chris@16	190 if(evalAtXforYdx1 == evalAtXforY0) return (Unit)evalAtXforYy1;
Chris@16	191 evalAtXforYx2 = other_pt.get(HORIZONTAL);
Chris@16	192 evalAtXforYy2 = other_pt.get(VERTICAL);
Chris@16	193
Chris@16	194 evalAtXforYdx = evalAtXforYx2 - evalAtXforYx1;
Chris@16	195 evalAtXforYdy = evalAtXforYy2 - evalAtXforYy1;
Chris@16	196 evalAtXforYret = ((evalAtXforYdx1) * evalAtXforYdy / evalAtXforYdx + evalAtXforYy1);
Chris@16	197 return (Unit)evalAtXforYret;
Chris@16	198 }
Chris@16	199
Chris@16	200 static inline typename high_precision_type<Unit>::type evalAtXforY(Unit xIn, Point pt, Point other_pt) {
Chris@16	201 typename high_precision_type<Unit>::type
Chris@16	202 evalAtXforYret, evalAtXforYxIn, evalAtXforYx1, evalAtXforYy1, evalAtXforYdx1, evalAtXforYdx,
Chris@16	203 evalAtXforYdy, evalAtXforYx2, evalAtXforYy2, evalAtXforY0;
Chris@16	204 //y = (x - x1)dy/dx + y1
Chris@16	205 //y = (xIn - pt.x)*(other_pt.y-pt.y)/(other_pt.x-pt.x) + pt.y
Chris@16	206 //assert pt.x != other_pt.x
Chris@16	207 typedef typename high_precision_type<Unit>::type high_precision;
Chris@16	208 if(pt.y() == other_pt.y())
Chris@16	209 return (high_precision)pt.y();
Chris@16	210 evalAtXforYxIn = (high_precision)xIn;
Chris@16	211 evalAtXforYx1 = pt.get(HORIZONTAL);
Chris@16	212 evalAtXforYy1 = pt.get(VERTICAL);
Chris@16	213 evalAtXforYdx1 = evalAtXforYxIn - evalAtXforYx1;
Chris@16	214 evalAtXforY0 = high_precision(0);
Chris@16	215 if(evalAtXforYdx1 == evalAtXforY0) return evalAtXforYret = evalAtXforYy1;
Chris@16	216 evalAtXforYx2 = (high_precision)other_pt.get(HORIZONTAL);
Chris@16	217 evalAtXforYy2 = (high_precision)other_pt.get(VERTICAL);
Chris@16	218
Chris@16	219 evalAtXforYdx = evalAtXforYx2 - evalAtXforYx1;
Chris@16	220 evalAtXforYdy = evalAtXforYy2 - evalAtXforYy1;
Chris@16	221 evalAtXforYret = ((evalAtXforYdx1) * evalAtXforYdy / evalAtXforYdx + evalAtXforYy1);
Chris@16	222 return evalAtXforYret;
Chris@16	223 }
Chris@16	224
Chris@16	225 struct evalAtXforYPack {
Chris@16	226 typename high_precision_type<Unit>::type
Chris@16	227 evalAtXforYret, evalAtXforYxIn, evalAtXforYx1, evalAtXforYy1, evalAtXforYdx1, evalAtXforYdx,
Chris@16	228 evalAtXforYdy, evalAtXforYx2, evalAtXforYy2, evalAtXforY0;
Chris@16	229 inline const typename high_precision_type<Unit>::type& evalAtXforY(Unit xIn, Point pt, Point other_pt) {
Chris@16	230 //y = (x - x1)dy/dx + y1
Chris@16	231 //y = (xIn - pt.x)*(other_pt.y-pt.y)/(other_pt.x-pt.x) + pt.y
Chris@16	232 //assert pt.x != other_pt.x
Chris@16	233 typedef typename high_precision_type<Unit>::type high_precision;
Chris@16	234 if(pt.y() == other_pt.y()) {
Chris@16	235 evalAtXforYret = (high_precision)pt.y();
Chris@16	236 return evalAtXforYret;
Chris@16	237 }
Chris@16	238 evalAtXforYxIn = (high_precision)xIn;
Chris@16	239 evalAtXforYx1 = pt.get(HORIZONTAL);
Chris@16	240 evalAtXforYy1 = pt.get(VERTICAL);
Chris@16	241 evalAtXforYdx1 = evalAtXforYxIn - evalAtXforYx1;
Chris@16	242 evalAtXforY0 = high_precision(0);
Chris@16	243 if(evalAtXforYdx1 == evalAtXforY0) return evalAtXforYret = evalAtXforYy1;
Chris@16	244 evalAtXforYx2 = (high_precision)other_pt.get(HORIZONTAL);
Chris@16	245 evalAtXforYy2 = (high_precision)other_pt.get(VERTICAL);
Chris@16	246
Chris@16	247 evalAtXforYdx = evalAtXforYx2 - evalAtXforYx1;
Chris@16	248 evalAtXforYdy = evalAtXforYy2 - evalAtXforYy1;
Chris@16	249 evalAtXforYret = ((evalAtXforYdx1) * evalAtXforYdy / evalAtXforYdx + evalAtXforYy1);
Chris@16	250 return evalAtXforYret;
Chris@16	251 }
Chris@16	252 };
Chris@16	253
Chris@16	254 static inline bool is_vertical(const half_edge& he) {
Chris@16	255 return he.first.get(HORIZONTAL) == he.second.get(HORIZONTAL);
Chris@16	256 }
Chris@16	257
Chris@16	258 static inline bool is_horizontal(const half_edge& he) {
Chris@16	259 return he.first.get(VERTICAL) == he.second.get(VERTICAL);
Chris@16	260 }
Chris@16	261
Chris@16	262 static inline bool is_45_degree(const half_edge& he) {
Chris@16	263 return euclidean_distance(he.first, he.second, HORIZONTAL) == euclidean_distance(he.first, he.second, VERTICAL);
Chris@16	264 }
Chris@16	265
Chris@16	266 //scanline comparator functor
Chris@16	267 class less_half_edge : public std::binary_function<half_edge, half_edge, bool> {
Chris@16	268 private:
Chris@16	269 Unit *x_; //x value at which to apply comparison
Chris@16	270 int *justBefore_;
Chris@16	271 evalAtXforYPack * pack_;
Chris@16	272 public:
Chris@16	273 inline less_half_edge() : x_(0), justBefore_(0), pack_(0) {}
Chris@16	274 inline less_half_edge(Unit x, int justBefore, evalAtXforYPack * packIn) : x_(x), justBefore_(justBefore), pack_(packIn) {}
Chris@16	275 inline less_half_edge(const less_half_edge& that) : x_(that.x_), justBefore_(that.justBefore_),
Chris@16	276 pack_(that.pack_){}
Chris@16	277 inline less_half_edge& operator=(const less_half_edge& that) {
Chris@16	278 x_ = that.x_;
Chris@16	279 justBefore_ = that.justBefore_;
Chris@16	280 pack_ = that.pack_;
Chris@16	281 return *this; }
Chris@16	282 inline bool operator () (const half_edge& elm1, const half_edge& elm2) const {
Chris@16	283 if((std::max)(elm1.first.y(), elm1.second.y()) < (std::min)(elm2.first.y(), elm2.second.y()))
Chris@16	284 return true;
Chris@16	285 if((std::min)(elm1.first.y(), elm1.second.y()) > (std::max)(elm2.first.y(), elm2.second.y()))
Chris@16	286 return false;
Chris@16	287
Chris@16	288 //check if either x of elem1 is equal to x_
Chris@16	289 Unit localx = *x_;
Chris@16	290 Unit elm1y = 0;
Chris@16	291 bool elm1_at_x = false;
Chris@16	292 if(localx == elm1.first.get(HORIZONTAL)) {
Chris@16	293 elm1_at_x = true;
Chris@16	294 elm1y = elm1.first.get(VERTICAL);
Chris@16	295 } else if(localx == elm1.second.get(HORIZONTAL)) {
Chris@16	296 elm1_at_x = true;
Chris@16	297 elm1y = elm1.second.get(VERTICAL);
Chris@16	298 }
Chris@16	299 Unit elm2y = 0;
Chris@16	300 bool elm2_at_x = false;
Chris@16	301 if(localx == elm2.first.get(HORIZONTAL)) {
Chris@16	302 elm2_at_x = true;
Chris@16	303 elm2y = elm2.first.get(VERTICAL);
Chris@16	304 } else if(localx == elm2.second.get(HORIZONTAL)) {
Chris@16	305 elm2_at_x = true;
Chris@16	306 elm2y = elm2.second.get(VERTICAL);
Chris@16	307 }
Chris@16	308 bool retval = false;
Chris@16	309 if(!(elm1_at_x && elm2_at_x)) {
Chris@16	310 //at least one of the segments doesn't have an end point a the current x
Chris@16	311 //-1 below, 1 above
Chris@16	312 int pt1_oab = on_above_or_below(elm1.first, half_edge(elm2.first, elm2.second));
Chris@16	313 int pt2_oab = on_above_or_below(elm1.second, half_edge(elm2.first, elm2.second));
Chris@16	314 if(pt1_oab == pt2_oab) {
Chris@16	315 if(pt1_oab == -1)
Chris@16	316 retval = true; //pt1 is below elm2 so elm1 is below elm2
Chris@16	317 } else {
Chris@16	318 //the segments can't cross so elm2 is on whatever side of elm1 that one of its ends is
Chris@16	319 int pt3_oab = on_above_or_below(elm2.first, half_edge(elm1.first, elm1.second));
Chris@16	320 if(pt3_oab == 1)
Chris@16	321 retval = true; //elm1's point is above elm1
Chris@16	322 }
Chris@16	323 } else {
Chris@16	324 if(elm1y < elm2y) {
Chris@16	325 retval = true;
Chris@16	326 } else if(elm1y == elm2y) {
Chris@16	327 if(elm1 == elm2)
Chris@16	328 return false;
Chris@16	329 retval = less_slope(elm1.second.get(HORIZONTAL) - elm1.first.get(HORIZONTAL),
Chris@16	330 elm1.second.get(VERTICAL) - elm1.first.get(VERTICAL),
Chris@16	331 elm2.second.get(HORIZONTAL) - elm2.first.get(HORIZONTAL),
Chris@16	332 elm2.second.get(VERTICAL) - elm2.first.get(VERTICAL));
Chris@16	333 retval = ((*justBefore_) != 0) ^ retval;
Chris@16	334 }
Chris@16	335 }
Chris@16	336 return retval;
Chris@16	337 }
Chris@16	338 };
Chris@16	339
Chris@16	340 template <typename unsigned_product_type>
Chris@16	341 static inline void unsigned_mod(unsigned_product_type& result, int& result_sign, unsigned_product_type a, int a_sign, unsigned_product_type b, int b_sign) {
Chris@16	342 result = a % b;
Chris@16	343 result_sign = a_sign;
Chris@16	344 }
Chris@16	345
Chris@16	346 template <typename unsigned_product_type>
Chris@16	347 static inline void unsigned_add(unsigned_product_type& result, int& result_sign, unsigned_product_type a, int a_sign, unsigned_product_type b, int b_sign) {
Chris@16	348 int switcher = 0;
Chris@16	349 if(a_sign < 0) switcher += 1;
Chris@16	350 if(b_sign < 0) switcher += 2;
Chris@16	351 if(a < b) switcher += 4;
Chris@16	352 switch (switcher) {
Chris@16	353 case 0: //both positive
Chris@16	354 result = a + b;
Chris@16	355 result_sign = 1;
Chris@16	356 break;
Chris@16	357 case 1: //a is negative
Chris@16	358 result = a - b;
Chris@16	359 result_sign = -1;
Chris@16	360 break;
Chris@16	361 case 2: //b is negative
Chris@16	362 result = a - b;
Chris@16	363 result_sign = 1;
Chris@16	364 break;
Chris@16	365 case 3: //both negative
Chris@16	366 result = a + b;
Chris@16	367 result_sign = -1;
Chris@16	368 break;
Chris@16	369 case 4: //both positive
Chris@16	370 result = a + b;
Chris@16	371 result_sign = 1;
Chris@16	372 break;
Chris@16	373 case 5: //a is negative
Chris@16	374 result = b - a;
Chris@16	375 result_sign = 1;
Chris@16	376 break;
Chris@16	377 case 6: //b is negative
Chris@16	378 result = b - a;
Chris@16	379 result_sign = -1;
Chris@16	380 break;
Chris@16	381 case 7: //both negative
Chris@16	382 result = b + a;
Chris@16	383 result_sign = -1;
Chris@16	384 break;
Chris@16	385 };
Chris@16	386 }
Chris@16	387
Chris@16	388 struct compute_intersection_pack {
Chris@16	389 typedef typename high_precision_type<Unit>::type high_precision;
Chris@16	390 high_precision y_high, dx1, dy1, dx2, dy2, x11, x21, y11, y21, x_num, y_num, x_den, y_den, x, y;
Chris@16	391 static inline bool compute_lazy_intersection(Point& intersection, const half_edge& he1, const half_edge& he2,
Chris@16	392 bool projected = false, bool round_closest = false) {
Chris@16	393 long double y_high, dx1, dy1, dx2, dy2, x11, x21, y11, y21, x_num, y_num, x_den, y_den, x, y;
Chris@16	394 typedef rectangle_data<Unit> Rectangle;
Chris@16	395 Rectangle rect1, rect2;
Chris@16	396 set_points(rect1, he1.first, he1.second);
Chris@16	397 set_points(rect2, he2.first, he2.second);
Chris@16	398 if(!projected && !::boost::polygon::intersects(rect1, rect2, true)) return false;
Chris@16	399 if(is_vertical(he1)) {
Chris@16	400 if(is_vertical(he2)) return false;
Chris@16	401 y_high = evalAtXforYlazy(he1.first.get(HORIZONTAL), he2.first, he2.second);
Chris@16	402 Unit y_local = (Unit)y_high;
Chris@16	403 if(y_high < y_local) --y_local;
Chris@16	404 if(projected \|\| contains(rect1.get(VERTICAL), y_local, true)) {
Chris@16	405 intersection = Point(he1.first.get(HORIZONTAL), y_local);
Chris@16	406 return true;
Chris@16	407 } else {
Chris@16	408 return false;
Chris@16	409 }
Chris@16	410 } else if(is_vertical(he2)) {
Chris@16	411 y_high = evalAtXforYlazy(he2.first.get(HORIZONTAL), he1.first, he1.second);
Chris@16	412 Unit y_local = (Unit)y_high;
Chris@16	413 if(y_high < y_local) --y_local;
Chris@16	414 if(projected \|\| contains(rect2.get(VERTICAL), y_local, true)) {
Chris@16	415 intersection = Point(he2.first.get(HORIZONTAL), y_local);
Chris@16	416 return true;
Chris@16	417 } else {
Chris@16	418 return false;
Chris@16	419 }
Chris@16	420 }
Chris@16	421 //the bounding boxes of the two line segments intersect, so we check closer to find the intersection point
Chris@16	422 dy2 = (he2.second.get(VERTICAL)) -
Chris@16	423 (he2.first.get(VERTICAL));
Chris@16	424 dy1 = (he1.second.get(VERTICAL)) -
Chris@16	425 (he1.first.get(VERTICAL));
Chris@16	426 dx2 = (he2.second.get(HORIZONTAL)) -
Chris@16	427 (he2.first.get(HORIZONTAL));
Chris@16	428 dx1 = (he1.second.get(HORIZONTAL)) -
Chris@16	429 (he1.first.get(HORIZONTAL));
Chris@16	430 if(equal_slope_hp(dx1, dy1, dx2, dy2)) return false;
Chris@16	431 //the line segments have different slopes
Chris@16	432 //we can assume that the line segments are not vertical because such an intersection is handled elsewhere
Chris@16	433 x11 = (he1.first.get(HORIZONTAL));
Chris@16	434 x21 = (he2.first.get(HORIZONTAL));
Chris@16	435 y11 = (he1.first.get(VERTICAL));
Chris@16	436 y21 = (he2.first.get(VERTICAL));
Chris@16	437 //Unit exp_x = ((at)x11 * (at)dy1 * (at)dx2 - (at)x21 * (at)dy2 * (at)dx1 + (at)y21 * (at)dx1 * (at)dx2 - (at)y11 * (at)dx1 * (at)dx2) / ((at)dy1 * (at)dx2 - (at)dy2 * (at)dx1);
Chris@16	438 //Unit exp_y = ((at)y11 * (at)dx1 * (at)dy2 - (at)y21 * (at)dx2 * (at)dy1 + (at)x21 * (at)dy1 * (at)dy2 - (at)x11 * (at)dy1 * (at)dy2) / ((at)dx1 * (at)dy2 - (at)dx2 * (at)dy1);
Chris@16	439 x_num = (x11 * dy1 * dx2 - x21 * dy2 * dx1 + y21 * dx1 * dx2 - y11 * dx1 * dx2);
Chris@16	440 x_den = (dy1 * dx2 - dy2 * dx1);
Chris@16	441 y_num = (y11 * dx1 * dy2 - y21 * dx2 * dy1 + x21 * dy1 * dy2 - x11 * dy1 * dy2);
Chris@16	442 y_den = (dx1 * dy2 - dx2 * dy1);
Chris@16	443 x = x_num / x_den;
Chris@16	444 y = y_num / y_den;
Chris@16	445 //std::cout << "cross1 " << dy1 << " " << dx2 << " " << dy1 * dx2 << "\n";
Chris@16	446 //std::cout << "cross2 " << dy2 << " " << dx1 << " " << dy2 * dx1 << "\n";
Chris@16	447 //Unit exp_x = compute_x_intercept<at>(x11, x21, y11, y21, dy1, dy2, dx1, dx2);
Chris@16	448 //Unit exp_y = compute_x_intercept<at>(y11, y21, x11, x21, dx1, dx2, dy1, dy2);
Chris@16	449 if(round_closest) {
Chris@16	450 x = x + 0.5;
Chris@16	451 y = y + 0.5;
Chris@16	452 }
Chris@16	453 Unit x_unit = (Unit)(x);
Chris@16	454 Unit y_unit = (Unit)(y);
Chris@16	455 //truncate downward if it went up due to negative number
Chris@16	456 if(x < x_unit) --x_unit;
Chris@16	457 if(y < y_unit) --y_unit;
Chris@16	458 if(is_horizontal(he1))
Chris@16	459 y_unit = he1.first.y();
Chris@16	460 if(is_horizontal(he2))
Chris@16	461 y_unit = he2.first.y();
Chris@16	462 //if(x != exp_x \|\| y != exp_y)
Chris@16	463 // std::cout << exp_x << " " << exp_y << " " << x << " " << y << "\n";
Chris@16	464 //Unit y1 = evalAtXforY(exp_x, he1.first, he1.second);
Chris@16	465 //Unit y2 = evalAtXforY(exp_x, he2.first, he2.second);
Chris@16	466 //std::cout << exp_x << " " << exp_y << " " << y1 << " " << y2 << "\n";
Chris@16	467 Point result(x_unit, y_unit);
Chris@16	468 if(!projected && !contains(rect1, result, true)) return false;
Chris@16	469 if(!projected && !contains(rect2, result, true)) return false;
Chris@16	470 if(projected) {
Chris@16	471 rectangle_data<long double> inf_rect(-(long double)(std::numeric_limits<Unit>::max)(),
Chris@16	472 -(long double) (std::numeric_limits<Unit>::max)(),
Chris@16	473 (long double)(std::numeric_limits<Unit>::max)(),
Chris@16	474 (long double) (std::numeric_limits<Unit>::max)() );
Chris@16	475 if(contains(inf_rect, point_data<long double>(x, y), true)) {
Chris@16	476 intersection = result;
Chris@16	477 return true;
Chris@16	478 } else
Chris@16	479 return false;
Chris@16	480 }
Chris@16	481 intersection = result;
Chris@16	482 return true;
Chris@16	483 }
Chris@16	484
Chris@16	485 inline bool compute_intersection(Point& intersection, const half_edge& he1, const half_edge& he2,
Chris@16	486 bool projected = false, bool round_closest = false) {
Chris@16	487 if(!projected && !intersects(he1, he2))
Chris@16	488 return false;
Chris@16	489 bool lazy_success = compute_lazy_intersection(intersection, he1, he2, projected);
Chris@16	490 if(!projected) {
Chris@16	491 if(lazy_success) {
Chris@16	492 if(intersects_grid(intersection, he1) &&
Chris@16	493 intersects_grid(intersection, he2))
Chris@16	494 return true;
Chris@16	495 }
Chris@16	496 } else {
Chris@16	497 return lazy_success;
Chris@16	498 }
Chris@16	499 return compute_exact_intersection(intersection, he1, he2, projected, round_closest);
Chris@16	500 }
Chris@16	501
Chris@16	502 inline bool compute_exact_intersection(Point& intersection, const half_edge& he1, const half_edge& he2,
Chris@16	503 bool projected = false, bool round_closest = false) {
Chris@16	504 if(!projected && !intersects(he1, he2))
Chris@16	505 return false;
Chris@16	506 typedef rectangle_data<Unit> Rectangle;
Chris@16	507 Rectangle rect1, rect2;
Chris@16	508 set_points(rect1, he1.first, he1.second);
Chris@16	509 set_points(rect2, he2.first, he2.second);
Chris@16	510 if(!::boost::polygon::intersects(rect1, rect2, true)) return false;
Chris@16	511 if(is_vertical(he1)) {
Chris@16	512 if(is_vertical(he2)) return false;
Chris@16	513 y_high = evalAtXforY(he1.first.get(HORIZONTAL), he2.first, he2.second);
Chris@16	514 Unit y = convert_high_precision_type<Unit>(y_high);
Chris@16	515 if(y_high < (high_precision)y) --y;
Chris@16	516 if(contains(rect1.get(VERTICAL), y, true)) {
Chris@16	517 intersection = Point(he1.first.get(HORIZONTAL), y);
Chris@16	518 return true;
Chris@16	519 } else {
Chris@16	520 return false;
Chris@16	521 }
Chris@16	522 } else if(is_vertical(he2)) {
Chris@16	523 y_high = evalAtXforY(he2.first.get(HORIZONTAL), he1.first, he1.second);
Chris@16	524 Unit y = convert_high_precision_type<Unit>(y_high);
Chris@16	525 if(y_high < (high_precision)y) --y;
Chris@16	526 if(contains(rect2.get(VERTICAL), y, true)) {
Chris@16	527 intersection = Point(he2.first.get(HORIZONTAL), y);
Chris@16	528 return true;
Chris@16	529 } else {
Chris@16	530 return false;
Chris@16	531 }
Chris@16	532 }
Chris@16	533 //the bounding boxes of the two line segments intersect, so we check closer to find the intersection point
Chris@16	534 dy2 = (high_precision)(he2.second.get(VERTICAL)) -
Chris@16	535 (high_precision)(he2.first.get(VERTICAL));
Chris@16	536 dy1 = (high_precision)(he1.second.get(VERTICAL)) -
Chris@16	537 (high_precision)(he1.first.get(VERTICAL));
Chris@16	538 dx2 = (high_precision)(he2.second.get(HORIZONTAL)) -
Chris@16	539 (high_precision)(he2.first.get(HORIZONTAL));
Chris@16	540 dx1 = (high_precision)(he1.second.get(HORIZONTAL)) -
Chris@16	541 (high_precision)(he1.first.get(HORIZONTAL));
Chris@16	542 if(equal_slope_hp(dx1, dy1, dx2, dy2)) return false;
Chris@16	543 //the line segments have different slopes
Chris@16	544 //we can assume that the line segments are not vertical because such an intersection is handled elsewhere
Chris@16	545 x11 = (high_precision)(he1.first.get(HORIZONTAL));
Chris@16	546 x21 = (high_precision)(he2.first.get(HORIZONTAL));
Chris@16	547 y11 = (high_precision)(he1.first.get(VERTICAL));
Chris@16	548 y21 = (high_precision)(he2.first.get(VERTICAL));
Chris@16	549 //Unit exp_x = ((at)x11 * (at)dy1 * (at)dx2 - (at)x21 * (at)dy2 * (at)dx1 + (at)y21 * (at)dx1 * (at)dx2 - (at)y11 * (at)dx1 * (at)dx2) / ((at)dy1 * (at)dx2 - (at)dy2 * (at)dx1);
Chris@16	550 //Unit exp_y = ((at)y11 * (at)dx1 * (at)dy2 - (at)y21 * (at)dx2 * (at)dy1 + (at)x21 * (at)dy1 * (at)dy2 - (at)x11 * (at)dy1 * (at)dy2) / ((at)dx1 * (at)dy2 - (at)dx2 * (at)dy1);
Chris@16	551 x_num = (x11 * dy1 * dx2 - x21 * dy2 * dx1 + y21 * dx1 * dx2 - y11 * dx1 * dx2);
Chris@16	552 x_den = (dy1 * dx2 - dy2 * dx1);
Chris@16	553 y_num = (y11 * dx1 * dy2 - y21 * dx2 * dy1 + x21 * dy1 * dy2 - x11 * dy1 * dy2);
Chris@16	554 y_den = (dx1 * dy2 - dx2 * dy1);
Chris@16	555 x = x_num / x_den;
Chris@16	556 y = y_num / y_den;
Chris@16	557 //std::cout << x << " " << y << "\n";
Chris@16	558 //std::cout << "cross1 " << dy1 << " " << dx2 << " " << dy1 * dx2 << "\n";
Chris@16	559 //std::cout << "cross2 " << dy2 << " " << dx1 << " " << dy2 * dx1 << "\n";
Chris@16	560 //Unit exp_x = compute_x_intercept<at>(x11, x21, y11, y21, dy1, dy2, dx1, dx2);
Chris@16	561 //Unit exp_y = compute_x_intercept<at>(y11, y21, x11, x21, dx1, dx2, dy1, dy2);
Chris@16	562 if(round_closest) {
Chris@16	563 x = x + (high_precision)0.5;
Chris@16	564 y = y + (high_precision)0.5;
Chris@16	565 }
Chris@16	566 Unit x_unit = convert_high_precision_type<Unit>(x);
Chris@16	567 Unit y_unit = convert_high_precision_type<Unit>(y);
Chris@16	568 //truncate downward if it went up due to negative number
Chris@16	569 if(x < (high_precision)x_unit) --x_unit;
Chris@16	570 if(y < (high_precision)y_unit) --y_unit;
Chris@16	571 if(is_horizontal(he1))
Chris@16	572 y_unit = he1.first.y();
Chris@16	573 if(is_horizontal(he2))
Chris@16	574 y_unit = he2.first.y();
Chris@16	575 //if(x != exp_x \|\| y != exp_y)
Chris@16	576 // std::cout << exp_x << " " << exp_y << " " << x << " " << y << "\n";
Chris@16	577 //Unit y1 = evalAtXforY(exp_x, he1.first, he1.second);
Chris@16	578 //Unit y2 = evalAtXforY(exp_x, he2.first, he2.second);
Chris@16	579 //std::cout << exp_x << " " << exp_y << " " << y1 << " " << y2 << "\n";
Chris@16	580 Point result(x_unit, y_unit);
Chris@16	581 if(!contains(rect1, result, true)) return false;
Chris@16	582 if(!contains(rect2, result, true)) return false;
Chris@16	583 if(projected) {
Chris@16	584 high_precision b1 = (high_precision) (std::numeric_limits<Unit>::min)();
Chris@16	585 high_precision b2 = (high_precision) (std::numeric_limits<Unit>::max)();
Chris@16	586 if(x > b2 \|\| y > b2 \|\| x < b1 \|\| y < b1)
Chris@16	587 return false;
Chris@16	588 }
Chris@16	589 intersection = result;
Chris@16	590 return true;
Chris@16	591 }
Chris@16	592 };
Chris@16	593
Chris@16	594 static inline bool compute_intersection(Point& intersection, const half_edge& he1, const half_edge& he2) {
Chris@16	595 typedef typename high_precision_type<Unit>::type high_precision;
Chris@16	596 typedef rectangle_data<Unit> Rectangle;
Chris@16	597 Rectangle rect1, rect2;
Chris@16	598 set_points(rect1, he1.first, he1.second);
Chris@16	599 set_points(rect2, he2.first, he2.second);
Chris@16	600 if(!::boost::polygon::intersects(rect1, rect2, true)) return false;
Chris@16	601 if(is_vertical(he1)) {
Chris@16	602 if(is_vertical(he2)) return false;
Chris@16	603 high_precision y_high = evalAtXforY(he1.first.get(HORIZONTAL), he2.first, he2.second);
Chris@16	604 Unit y = convert_high_precision_type<Unit>(y_high);
Chris@16	605 if(y_high < (high_precision)y) --y;
Chris@16	606 if(contains(rect1.get(VERTICAL), y, true)) {
Chris@16	607 intersection = Point(he1.first.get(HORIZONTAL), y);
Chris@16	608 return true;
Chris@16	609 } else {
Chris@16	610 return false;
Chris@16	611 }
Chris@16	612 } else if(is_vertical(he2)) {
Chris@16	613 high_precision y_high = evalAtXforY(he2.first.get(HORIZONTAL), he1.first, he1.second);
Chris@16	614 Unit y = convert_high_precision_type<Unit>(y_high);
Chris@16	615 if(y_high < (high_precision)y) --y;
Chris@16	616 if(contains(rect2.get(VERTICAL), y, true)) {
Chris@16	617 intersection = Point(he2.first.get(HORIZONTAL), y);
Chris@16	618 return true;
Chris@16	619 } else {
Chris@16	620 return false;
Chris@16	621 }
Chris@16	622 }
Chris@16	623 //the bounding boxes of the two line segments intersect, so we check closer to find the intersection point
Chris@16	624 high_precision dy2 = (high_precision)(he2.second.get(VERTICAL)) -
Chris@16	625 (high_precision)(he2.first.get(VERTICAL));
Chris@16	626 high_precision dy1 = (high_precision)(he1.second.get(VERTICAL)) -
Chris@16	627 (high_precision)(he1.first.get(VERTICAL));
Chris@16	628 high_precision dx2 = (high_precision)(he2.second.get(HORIZONTAL)) -
Chris@16	629 (high_precision)(he2.first.get(HORIZONTAL));
Chris@16	630 high_precision dx1 = (high_precision)(he1.second.get(HORIZONTAL)) -
Chris@16	631 (high_precision)(he1.first.get(HORIZONTAL));
Chris@16	632 if(equal_slope_hp(dx1, dy1, dx2, dy2)) return false;
Chris@16	633 //the line segments have different slopes
Chris@16	634 //we can assume that the line segments are not vertical because such an intersection is handled elsewhere
Chris@16	635 high_precision x11 = (high_precision)(he1.first.get(HORIZONTAL));
Chris@16	636 high_precision x21 = (high_precision)(he2.first.get(HORIZONTAL));
Chris@16	637 high_precision y11 = (high_precision)(he1.first.get(VERTICAL));
Chris@16	638 high_precision y21 = (high_precision)(he2.first.get(VERTICAL));
Chris@16	639 //Unit exp_x = ((at)x11 * (at)dy1 * (at)dx2 - (at)x21 * (at)dy2 * (at)dx1 + (at)y21 * (at)dx1 * (at)dx2 - (at)y11 * (at)dx1 * (at)dx2) / ((at)dy1 * (at)dx2 - (at)dy2 * (at)dx1);
Chris@16	640 //Unit exp_y = ((at)y11 * (at)dx1 * (at)dy2 - (at)y21 * (at)dx2 * (at)dy1 + (at)x21 * (at)dy1 * (at)dy2 - (at)x11 * (at)dy1 * (at)dy2) / ((at)dx1 * (at)dy2 - (at)dx2 * (at)dy1);
Chris@16	641 high_precision x_num = (x11 * dy1 * dx2 - x21 * dy2 * dx1 + y21 * dx1 * dx2 - y11 * dx1 * dx2);
Chris@16	642 high_precision x_den = (dy1 * dx2 - dy2 * dx1);
Chris@16	643 high_precision y_num = (y11 * dx1 * dy2 - y21 * dx2 * dy1 + x21 * dy1 * dy2 - x11 * dy1 * dy2);
Chris@16	644 high_precision y_den = (dx1 * dy2 - dx2 * dy1);
Chris@16	645 high_precision x = x_num / x_den;
Chris@16	646 high_precision y = y_num / y_den;
Chris@16	647 //std::cout << "cross1 " << dy1 << " " << dx2 << " " << dy1 * dx2 << "\n";
Chris@16	648 //std::cout << "cross2 " << dy2 << " " << dx1 << " " << dy2 * dx1 << "\n";
Chris@16	649 //Unit exp_x = compute_x_intercept<at>(x11, x21, y11, y21, dy1, dy2, dx1, dx2);
Chris@16	650 //Unit exp_y = compute_x_intercept<at>(y11, y21, x11, x21, dx1, dx2, dy1, dy2);
Chris@16	651 Unit x_unit = convert_high_precision_type<Unit>(x);
Chris@16	652 Unit y_unit = convert_high_precision_type<Unit>(y);
Chris@16	653 //truncate downward if it went up due to negative number
Chris@16	654 if(x < (high_precision)x_unit) --x_unit;
Chris@16	655 if(y < (high_precision)y_unit) --y_unit;
Chris@16	656 if(is_horizontal(he1))
Chris@16	657 y_unit = he1.first.y();
Chris@16	658 if(is_horizontal(he2))
Chris@16	659 y_unit = he2.first.y();
Chris@16	660 //if(x != exp_x \|\| y != exp_y)
Chris@16	661 // std::cout << exp_x << " " << exp_y << " " << x << " " << y << "\n";
Chris@16	662 //Unit y1 = evalAtXforY(exp_x, he1.first, he1.second);
Chris@16	663 //Unit y2 = evalAtXforY(exp_x, he2.first, he2.second);
Chris@16	664 //std::cout << exp_x << " " << exp_y << " " << y1 << " " << y2 << "\n";
Chris@16	665 Point result(x_unit, y_unit);
Chris@16	666 if(!contains(rect1, result, true)) return false;
Chris@16	667 if(!contains(rect2, result, true)) return false;
Chris@16	668 intersection = result;
Chris@16	669 return true;
Chris@16	670 }
Chris@16	671
Chris@16	672 static inline bool intersects(const half_edge& he1, const half_edge& he2) {
Chris@16	673 typedef rectangle_data<Unit> Rectangle;
Chris@16	674 Rectangle rect1, rect2;
Chris@16	675 set_points(rect1, he1.first, he1.second);
Chris@16	676 set_points(rect2, he2.first, he2.second);
Chris@16	677 if(::boost::polygon::intersects(rect1, rect2, false)) {
Chris@16	678 if(he1.first == he2.first) {
Chris@16	679 if(he1.second != he2.second && equal_slope(he1.first.get(HORIZONTAL), he1.first.get(VERTICAL),
Chris@16	680 he1.second, he2.second)) {
Chris@16	681 return true;
Chris@16	682 } else {
Chris@16	683 return false;
Chris@16	684 }
Chris@16	685 }
Chris@16	686 if(he1.first == he2.second) {
Chris@16	687 if(he1.second != he2.first && equal_slope(he1.first.get(HORIZONTAL), he1.first.get(VERTICAL),
Chris@16	688 he1.second, he2.first)) {
Chris@16	689 return true;
Chris@16	690 } else {
Chris@16	691 return false;
Chris@16	692 }
Chris@16	693 }
Chris@16	694 if(he1.second == he2.first) {
Chris@16	695 if(he1.first != he2.second && equal_slope(he1.second.get(HORIZONTAL), he1.second.get(VERTICAL),
Chris@16	696 he1.first, he2.second)) {
Chris@16	697 return true;
Chris@16	698 } else {
Chris@16	699 return false;
Chris@16	700 }
Chris@16	701 }
Chris@16	702 if(he1.second == he2.second) {
Chris@16	703 if(he1.first != he2.first && equal_slope(he1.second.get(HORIZONTAL), he1.second.get(VERTICAL),
Chris@16	704 he1.first, he2.first)) {
Chris@16	705 return true;
Chris@16	706 } else {
Chris@16	707 return false;
Chris@16	708 }
Chris@16	709 }
Chris@16	710 int oab1 = on_above_or_below(he1.first, he2);
Chris@16	711 if(oab1 == 0 && between(he1.first, he2.first, he2.second)) return true;
Chris@16	712 int oab2 = on_above_or_below(he1.second, he2);
Chris@16	713 if(oab2 == 0 && between(he1.second, he2.first, he2.second)) return true;
Chris@16	714 if(oab1 == oab2 && oab1 != 0) return false; //both points of he1 are on same side of he2
Chris@16	715 int oab3 = on_above_or_below(he2.first, he1);
Chris@16	716 if(oab3 == 0 && between(he2.first, he1.first, he1.second)) return true;
Chris@16	717 int oab4 = on_above_or_below(he2.second, he1);
Chris@16	718 if(oab4 == 0 && between(he2.second, he1.first, he1.second)) return true;
Chris@16	719 if(oab3 == oab4) return false; //both points of he2 are on same side of he1
Chris@16	720 return true; //they must cross
Chris@16	721 }
Chris@16	722 if(is_vertical(he1) && is_vertical(he2) && he1.first.get(HORIZONTAL) == he2.first.get(HORIZONTAL))
Chris@16	723 return ::boost::polygon::intersects(rect1.get(VERTICAL), rect2.get(VERTICAL), false) &&
Chris@16	724 rect1.get(VERTICAL) != rect2.get(VERTICAL);
Chris@16	725 if(is_horizontal(he1) && is_horizontal(he2) && he1.first.get(VERTICAL) == he2.first.get(VERTICAL))
Chris@16	726 return ::boost::polygon::intersects(rect1.get(HORIZONTAL), rect2.get(HORIZONTAL), false) &&
Chris@16	727 rect1.get(HORIZONTAL) != rect2.get(HORIZONTAL);
Chris@16	728 return false;
Chris@16	729 }
Chris@16	730
Chris@16	731 class vertex_half_edge {
Chris@16	732 public:
Chris@16	733 typedef typename high_precision_type<Unit>::type high_precision;
Chris@16	734 Point pt;
Chris@16	735 Point other_pt; // 1, 0 or -1
Chris@16	736 int count; //dxdydTheta
Chris@16	737 inline vertex_half_edge() : pt(), other_pt(), count() {}
Chris@16	738 inline vertex_half_edge(const Point& point, const Point& other_point, int countIn) : pt(point), other_pt(other_point), count(countIn) {}
Chris@16	739 inline vertex_half_edge(const vertex_half_edge& vertex) : pt(vertex.pt), other_pt(vertex.other_pt), count(vertex.count) {}
Chris@16	740 inline vertex_half_edge& operator=(const vertex_half_edge& vertex){
Chris@16	741 pt = vertex.pt; other_pt = vertex.other_pt; count = vertex.count; return *this; }
Chris@16	742 inline vertex_half_edge(const std::pair<Point, Point>& vertex) : pt(), other_pt(), count() {}
Chris@16	743 inline vertex_half_edge& operator=(const std::pair<Point, Point>& vertex){ return *this; }
Chris@16	744 inline bool operator==(const vertex_half_edge& vertex) const {
Chris@16	745 return pt == vertex.pt && other_pt == vertex.other_pt && count == vertex.count; }
Chris@16	746 inline bool operator!=(const vertex_half_edge& vertex) const { return !((*this) == vertex); }
Chris@16	747 inline bool operator==(const std::pair<Point, Point>& vertex) const { return false; }
Chris@16	748 inline bool operator!=(const std::pair<Point, Point>& vertex) const { return !((*this) == vertex); }
Chris@16	749 inline bool operator<(const vertex_half_edge& vertex) const {
Chris@16	750 if(pt.get(HORIZONTAL) < vertex.pt.get(HORIZONTAL)) return true;
Chris@16	751 if(pt.get(HORIZONTAL) == vertex.pt.get(HORIZONTAL)) {
Chris@16	752 if(pt.get(VERTICAL) < vertex.pt.get(VERTICAL)) return true;
Chris@16	753 if(pt.get(VERTICAL) == vertex.pt.get(VERTICAL)) { return less_slope(pt.get(HORIZONTAL), pt.get(VERTICAL),
Chris@16	754 other_pt, vertex.other_pt);
Chris@16	755 }
Chris@16	756 }
Chris@16	757 return false;
Chris@16	758 }
Chris@16	759 inline bool operator>(const vertex_half_edge& vertex) const { return vertex < (*this); }
Chris@16	760 inline bool operator<=(const vertex_half_edge& vertex) const { return !((*this) > vertex); }
Chris@16	761 inline bool operator>=(const vertex_half_edge& vertex) const { return !((*this) < vertex); }
Chris@16	762 inline high_precision evalAtX(Unit xIn) const { return evalAtXforYlazy(xIn, pt, other_pt); }
Chris@16	763 inline bool is_vertical() const {
Chris@16	764 return pt.get(HORIZONTAL) == other_pt.get(HORIZONTAL);
Chris@16	765 }
Chris@16	766 inline bool is_begin() const {
Chris@16	767 return pt.get(HORIZONTAL) < other_pt.get(HORIZONTAL) \|\|
Chris@16	768 (pt.get(HORIZONTAL) == other_pt.get(HORIZONTAL) &&
Chris@16	769 (pt.get(VERTICAL) < other_pt.get(VERTICAL)));
Chris@16	770 }
Chris@16	771 };
Chris@16	772
Chris@16	773 //when scanning Vertex45 for polygon formation we need a scanline comparator functor
Chris@16	774 class less_vertex_half_edge : public std::binary_function<vertex_half_edge, vertex_half_edge, bool> {
Chris@16	775 private:
Chris@16	776 Unit *x_; //x value at which to apply comparison
Chris@16	777 int *justBefore_;
Chris@16	778 public:
Chris@16	779 inline less_vertex_half_edge() : x_(0), justBefore_(0) {}
Chris@16	780 inline less_vertex_half_edge(Unit x, int justBefore) : x_(x), justBefore_(justBefore) {}
Chris@16	781 inline less_vertex_half_edge(const less_vertex_half_edge& that) : x_(that.x_), justBefore_(that.justBefore_) {}
Chris@16	782 inline less_vertex_half_edge& operator=(const less_vertex_half_edge& that) { x_ = that.x_; justBefore_ = that.justBefore_; return *this; }
Chris@16	783 inline bool operator () (const vertex_half_edge& elm1, const vertex_half_edge& elm2) const {
Chris@16	784 if((std::max)(elm1.pt.y(), elm1.other_pt.y()) < (std::min)(elm2.pt.y(), elm2.other_pt.y()))
Chris@16	785 return true;
Chris@16	786 if((std::min)(elm1.pt.y(), elm1.other_pt.y()) > (std::max)(elm2.pt.y(), elm2.other_pt.y()))
Chris@16	787 return false;
Chris@16	788 //check if either x of elem1 is equal to x_
Chris@16	789 Unit localx = *x_;
Chris@16	790 Unit elm1y = 0;
Chris@16	791 bool elm1_at_x = false;
Chris@16	792 if(localx == elm1.pt.get(HORIZONTAL)) {
Chris@16	793 elm1_at_x = true;
Chris@16	794 elm1y = elm1.pt.get(VERTICAL);
Chris@16	795 } else if(localx == elm1.other_pt.get(HORIZONTAL)) {
Chris@16	796 elm1_at_x = true;
Chris@16	797 elm1y = elm1.other_pt.get(VERTICAL);
Chris@16	798 }
Chris@16	799 Unit elm2y = 0;
Chris@16	800 bool elm2_at_x = false;
Chris@16	801 if(localx == elm2.pt.get(HORIZONTAL)) {
Chris@16	802 elm2_at_x = true;
Chris@16	803 elm2y = elm2.pt.get(VERTICAL);
Chris@16	804 } else if(localx == elm2.other_pt.get(HORIZONTAL)) {
Chris@16	805 elm2_at_x = true;
Chris@16	806 elm2y = elm2.other_pt.get(VERTICAL);
Chris@16	807 }
Chris@16	808 bool retval = false;
Chris@16	809 if(!(elm1_at_x && elm2_at_x)) {
Chris@16	810 //at least one of the segments doesn't have an end point a the current x
Chris@16	811 //-1 below, 1 above
Chris@16	812 int pt1_oab = on_above_or_below(elm1.pt, half_edge(elm2.pt, elm2.other_pt));
Chris@16	813 int pt2_oab = on_above_or_below(elm1.other_pt, half_edge(elm2.pt, elm2.other_pt));
Chris@16	814 if(pt1_oab == pt2_oab) {
Chris@16	815 if(pt1_oab == -1)
Chris@16	816 retval = true; //pt1 is below elm2 so elm1 is below elm2
Chris@16	817 } else {
Chris@16	818 //the segments can't cross so elm2 is on whatever side of elm1 that one of its ends is
Chris@16	819 int pt3_oab = on_above_or_below(elm2.pt, half_edge(elm1.pt, elm1.other_pt));
Chris@16	820 if(pt3_oab == 1)
Chris@16	821 retval = true; //elm1's point is above elm1
Chris@16	822 }
Chris@16	823 } else {
Chris@16	824 if(elm1y < elm2y) {
Chris@16	825 retval = true;
Chris@16	826 } else if(elm1y == elm2y) {
Chris@16	827 if(elm1.pt == elm2.pt && elm1.other_pt == elm2.other_pt)
Chris@16	828 return false;
Chris@16	829 retval = less_slope(elm1.other_pt.get(HORIZONTAL) - elm1.pt.get(HORIZONTAL),
Chris@16	830 elm1.other_pt.get(VERTICAL) - elm1.pt.get(VERTICAL),
Chris@16	831 elm2.other_pt.get(HORIZONTAL) - elm2.pt.get(HORIZONTAL),
Chris@16	832 elm2.other_pt.get(VERTICAL) - elm2.pt.get(VERTICAL));
Chris@16	833 retval = ((*justBefore_) != 0) ^ retval;
Chris@16	834 }
Chris@16	835 }
Chris@16	836 return retval;
Chris@16	837 }
Chris@16	838 };
Chris@16	839
Chris@16	840 };
Chris@16	841
Chris@16	842 template <typename Unit>
Chris@16	843 class polygon_arbitrary_formation : public scanline_base<Unit> {
Chris@16	844 public:
Chris@16	845 typedef typename scanline_base<Unit>::Point Point;
Chris@16	846 typedef typename scanline_base<Unit>::half_edge half_edge;
Chris@16	847 typedef typename scanline_base<Unit>::vertex_half_edge vertex_half_edge;
Chris@16	848 typedef typename scanline_base<Unit>::less_vertex_half_edge less_vertex_half_edge;
Chris@16	849
Chris@16	850 class poly_line_arbitrary {
Chris@16	851 public:
Chris@16	852 typedef typename std::list<Point>::const_iterator iterator;
Chris@16	853
Chris@16	854 // default constructor of point does not initialize x and y
Chris@16	855 inline poly_line_arbitrary() : points() {} //do nothing default constructor
Chris@16	856
Chris@16	857 // initialize a polygon from x,y values, it is assumed that the first is an x
Chris@16	858 // and that the input is a well behaved polygon
Chris@16	859 template<class iT>
Chris@16	860 inline poly_line_arbitrary& set(iT inputBegin, iT inputEnd) {
Chris@16	861 points.clear(); //just in case there was some old data there
Chris@16	862 while(inputBegin != inputEnd) {
Chris@16	863 points.insert(points.end(), *inputBegin);
Chris@16	864 ++inputBegin;
Chris@16	865 }
Chris@16	866 return *this;
Chris@16	867 }
Chris@16	868
Chris@16	869 // copy constructor (since we have dynamic memory)
Chris@16	870 inline poly_line_arbitrary(const poly_line_arbitrary& that) : points(that.points) {}
Chris@16	871
Chris@16	872 // assignment operator (since we have dynamic memory do a deep copy)
Chris@16	873 inline poly_line_arbitrary& operator=(const poly_line_arbitrary& that) {
Chris@16	874 points = that.points;
Chris@16	875 return *this;
Chris@16	876 }
Chris@16	877
Chris@16	878 // get begin iterator, returns a pointer to a const Unit
Chris@16	879 inline iterator begin() const { return points.begin(); }
Chris@16	880
Chris@16	881 // get end iterator, returns a pointer to a const Unit
Chris@16	882 inline iterator end() const { return points.end(); }
Chris@16	883
Chris@16	884 inline std::size_t size() const { return points.size(); }
Chris@16	885
Chris@16	886 //public data member
Chris@16	887 std::list<Point> points;
Chris@16	888 };
Chris@16	889
Chris@16	890 class active_tail_arbitrary {
Chris@16	891 protected:
Chris@16	892 //data
Chris@16	893 poly_line_arbitrary* tailp_;
Chris@16	894 active_tail_arbitrary *otherTailp_;
Chris@16	895 std::list<active_tail_arbitrary*> holesList_;
Chris@16	896 bool head_;
Chris@16	897 public:
Chris@16	898
Chris@16	899 /**
Chris@16	900 * @brief iterator over coordinates of the figure
Chris@16	901 */
Chris@16	902 typedef typename poly_line_arbitrary::iterator iterator;
Chris@16	903
Chris@16	904 /**
Chris@16	905 * @brief iterator over holes contained within the figure
Chris@16	906 */
Chris@16	907 typedef typename std::list<active_tail_arbitrary*>::const_iterator iteratorHoles;
Chris@16	908
Chris@16	909 //default constructor
Chris@16	910 inline active_tail_arbitrary() : tailp_(), otherTailp_(), holesList_(), head_() {}
Chris@16	911
Chris@16	912 //constructor
Chris@16	913 inline active_tail_arbitrary(const vertex_half_edge& vertex, active_tail_arbitrary* otherTailp = 0) : tailp_(), otherTailp_(), holesList_(), head_() {
Chris@16	914 tailp_ = new poly_line_arbitrary;
Chris@16	915 tailp_->points.push_back(vertex.pt);
Chris@16	916 //bool headArray[4] = {false, true, true, true};
Chris@16	917 bool inverted = vertex.count == -1;
Chris@16	918 head_ = (!vertex.is_vertical) ^ inverted;
Chris@16	919 otherTailp_ = otherTailp;
Chris@16	920 }
Chris@16	921
Chris@16	922 inline active_tail_arbitrary(Point point, active_tail_arbitrary* otherTailp, bool head = true) :
Chris@16	923 tailp_(), otherTailp_(), holesList_(), head_() {
Chris@16	924 tailp_ = new poly_line_arbitrary;
Chris@16	925 tailp_->points.push_back(point);
Chris@16	926 head_ = head;
Chris@16	927 otherTailp_ = otherTailp;
Chris@16	928
Chris@16	929 }
Chris@16	930 inline active_tail_arbitrary(active_tail_arbitrary* otherTailp) :
Chris@16	931 tailp_(), otherTailp_(), holesList_(), head_() {
Chris@16	932 tailp_ = otherTailp->tailp_;
Chris@16	933 otherTailp_ = otherTailp;
Chris@16	934 }
Chris@16	935
Chris@16	936 //copy constructor
Chris@16	937 inline active_tail_arbitrary(const active_tail_arbitrary& that) :
Chris@16	938 tailp_(), otherTailp_(), holesList_(), head_() { (*this) = that; }
Chris@16	939
Chris@16	940 //destructor
Chris@16	941 inline ~active_tail_arbitrary() {
Chris@16	942 destroyContents();
Chris@16	943 }
Chris@16	944
Chris@16	945 //assignment operator
Chris@16	946 inline active_tail_arbitrary& operator=(const active_tail_arbitrary& that) {
Chris@16	947 tailp_ = new poly_line_arbitrary(*(that.tailp_));
Chris@16	948 head_ = that.head_;
Chris@16	949 otherTailp_ = that.otherTailp_;
Chris@16	950 holesList_ = that.holesList_;
Chris@16	951 return *this;
Chris@16	952 }
Chris@16	953
Chris@16	954 //equivalence operator
Chris@16	955 inline bool operator==(const active_tail_arbitrary& b) const {
Chris@16	956 return tailp_ == b.tailp_ && head_ == b.head_;
Chris@16	957 }
Chris@16	958
Chris@16	959 /**
Chris@16	960 * @brief get the pointer to the polyline that this is an active tail of
Chris@16	961 */
Chris@16	962 inline poly_line_arbitrary* getTail() const { return tailp_; }
Chris@16	963
Chris@16	964 /**
Chris@16	965 * @brief get the pointer to the polyline at the other end of the chain
Chris@16	966 */
Chris@16	967 inline poly_line_arbitrary* getOtherTail() const { return otherTailp_->tailp_; }
Chris@16	968
Chris@16	969 /**
Chris@16	970 * @brief get the pointer to the activetail at the other end of the chain
Chris@16	971 */
Chris@16	972 inline active_tail_arbitrary* getOtherActiveTail() const { return otherTailp_; }
Chris@16	973
Chris@16	974 /**
Chris@16	975 * @brief test if another active tail is the other end of the chain
Chris@16	976 */
Chris@16	977 inline bool isOtherTail(const active_tail_arbitrary& b) const { return &b == otherTailp_; }
Chris@16	978
Chris@16	979 /**
Chris@16	980 * @brief update this end of chain pointer to new polyline
Chris@16	981 */
Chris@16	982 inline active_tail_arbitrary& updateTail(poly_line_arbitrary* newTail) { tailp_ = newTail; return *this; }
Chris@16	983
Chris@16	984 inline bool join(active_tail_arbitrary* tail) {
Chris@16	985 if(tail == otherTailp_) {
Chris@16	986 //std::cout << "joining to other tail!\n";
Chris@16	987 return false;
Chris@16	988 }
Chris@16	989 if(tail->head_ == head_) {
Chris@16	990 //std::cout << "joining head to head!\n";
Chris@16	991 return false;
Chris@16	992 }
Chris@16	993 if(!tailp_) {
Chris@16	994 //std::cout << "joining empty tail!\n";
Chris@16	995 return false;
Chris@16	996 }
Chris@16	997 if(!(otherTailp_->head_)) {
Chris@16	998 otherTailp_->copyHoles(*tail);
Chris@16	999 otherTailp_->copyHoles(*this);
Chris@16	1000 } else {
Chris@16	1001 tail->otherTailp_->copyHoles(*this);
Chris@16	1002 tail->otherTailp_->copyHoles(*tail);
Chris@16	1003 }
Chris@16	1004 poly_line_arbitrary* tail1 = tailp_;
Chris@16	1005 poly_line_arbitrary* tail2 = tail->tailp_;
Chris@16	1006 if(head_) std::swap(tail1, tail2);
Chris@16	1007 typename std::list<point_data<Unit> >::reverse_iterator riter = tail1->points.rbegin();
Chris@16	1008 typename std::list<point_data<Unit> >::iterator iter = tail2->points.begin();
Chris@16	1009 if(riter == iter) {
Chris@16	1010 tail1->points.pop_back(); //remove duplicate point
Chris@16	1011 }
Chris@16	1012 tail1->points.splice(tail1->points.end(), tail2->points);
Chris@16	1013 delete tail2;
Chris@16	1014 otherTailp_->tailp_ = tail1;
Chris@16	1015 tail->otherTailp_->tailp_ = tail1;
Chris@16	1016 otherTailp_->otherTailp_ = tail->otherTailp_;
Chris@16	1017 tail->otherTailp_->otherTailp_ = otherTailp_;
Chris@16	1018 tailp_ = 0;
Chris@16	1019 tail->tailp_ = 0;
Chris@16	1020 tail->otherTailp_ = 0;
Chris@16	1021 otherTailp_ = 0;
Chris@16	1022 return true;
Chris@16	1023 }
Chris@16	1024
Chris@16	1025 /**
Chris@16	1026 * @brief associate a hole to this active tail by the specified policy
Chris@16	1027 */
Chris@16	1028 inline active_tail_arbitrary* addHole(active_tail_arbitrary* hole) {
Chris@16	1029 holesList_.push_back(hole);
Chris@16	1030 copyHoles(*hole);
Chris@16	1031 copyHoles(*(hole->otherTailp_));
Chris@16	1032 return this;
Chris@16	1033 }
Chris@16	1034
Chris@16	1035 /**
Chris@16	1036 * @brief get the list of holes
Chris@16	1037 */
Chris@16	1038 inline const std::list<active_tail_arbitrary*>& getHoles() const { return holesList_; }
Chris@16	1039
Chris@16	1040 /**
Chris@16	1041 * @brief copy holes from that to this
Chris@16	1042 */
Chris@16	1043 inline void copyHoles(active_tail_arbitrary& that) { holesList_.splice(holesList_.end(), that.holesList_); }
Chris@16	1044
Chris@16	1045 /**
Chris@16	1046 * @brief find out if solid to right
Chris@16	1047 */
Chris@16	1048 inline bool solidToRight() const { return !head_; }
Chris@16	1049 inline bool solidToLeft() const { return head_; }
Chris@16	1050
Chris@16	1051 /**
Chris@16	1052 * @brief get vertex
Chris@16	1053 */
Chris@16	1054 inline Point getPoint() const {
Chris@16	1055 if(head_) return tailp_->points.front();
Chris@16	1056 return tailp_->points.back();
Chris@16	1057 }
Chris@16	1058
Chris@16	1059 /**
Chris@16	1060 * @brief add a coordinate to the polygon at this active tail end, properly handle degenerate edges by removing redundant coordinate
Chris@16	1061 */
Chris@16	1062 inline void pushPoint(Point point) {
Chris@16	1063 if(head_) {
Chris@16	1064 //if(tailp_->points.size() < 2) {
Chris@16	1065 // tailp_->points.push_front(point);
Chris@16	1066 // return;
Chris@16	1067 //}
Chris@16	1068 typename std::list<Point>::iterator iter = tailp_->points.begin();
Chris@16	1069 if(iter == tailp_->points.end()) {
Chris@16	1070 tailp_->points.push_front(point);
Chris@16	1071 return;
Chris@16	1072 }
Chris@16	1073 ++iter;
Chris@16	1074 if(iter == tailp_->points.end()) {
Chris@16	1075 tailp_->points.push_front(point);
Chris@16	1076 return;
Chris@16	1077 }
Chris@16	1078 --iter;
Chris@16	1079 if(*iter != point) {
Chris@16	1080 tailp_->points.push_front(point);
Chris@16	1081 }
Chris@16	1082 return;
Chris@16	1083 }
Chris@16	1084 //if(tailp_->points.size() < 2) {
Chris@16	1085 // tailp_->points.push_back(point);
Chris@16	1086 // return;
Chris@16	1087 //}
Chris@16	1088 typename std::list<Point>::reverse_iterator iter = tailp_->points.rbegin();
Chris@16	1089 if(iter == tailp_->points.rend()) {
Chris@16	1090 tailp_->points.push_back(point);
Chris@16	1091 return;
Chris@16	1092 }
Chris@16	1093 ++iter;
Chris@16	1094 if(iter == tailp_->points.rend()) {
Chris@16	1095 tailp_->points.push_back(point);
Chris@16	1096 return;
Chris@16	1097 }
Chris@16	1098 --iter;
Chris@16	1099 if(*iter != point) {
Chris@16	1100 tailp_->points.push_back(point);
Chris@16	1101 }
Chris@16	1102 }
Chris@16	1103
Chris@16	1104 /**
Chris@16	1105 * @brief joins the two chains that the two active tail tails are ends of
Chris@16	1106 * checks for closure of figure and writes out polygons appropriately
Chris@16	1107 * returns a handle to a hole if one is closed
Chris@16	1108 */
Chris@16	1109 template <class cT>
Chris@16	1110 static inline active_tail_arbitrary* joinChains(Point point, active_tail_arbitrary* at1, active_tail_arbitrary* at2, bool solid,
Chris@16	1111 cT& output) {
Chris@16	1112 if(at1->otherTailp_ == at2) {
Chris@16	1113 //if(at2->otherTailp_ != at1) std::cout << "half closed error\n";
Chris@16	1114 //we are closing a figure
Chris@16	1115 at1->pushPoint(point);
Chris@16	1116 at2->pushPoint(point);
Chris@16	1117 if(solid) {
Chris@16	1118 //we are closing a solid figure, write to output
Chris@16	1119 //std::cout << "test1\n";
Chris@16	1120 at1->copyHoles(*(at1->otherTailp_));
Chris@16	1121 typename PolyLineArbitraryByConcept<Unit, typename geometry_concept<typename cT::value_type>::type>::type polyData(at1);
Chris@16	1122 //poly_line_arbitrary_polygon_data polyData(at1);
Chris@16	1123 //std::cout << "test2\n";
Chris@16	1124 //std::cout << poly << "\n";
Chris@16	1125 //std::cout << "test3\n";
Chris@16	1126 typedef typename cT::value_type result_type;
Chris@16	1127 output.push_back(result_type());
Chris@16	1128 assign(output.back(), polyData);
Chris@16	1129 //std::cout << "test4\n";
Chris@16	1130 //std::cout << "delete " << at1->otherTailp_ << "\n";
Chris@16	1131 //at1->print();
Chris@16	1132 //at1->otherTailp_->print();
Chris@16	1133 delete at1->otherTailp_;
Chris@16	1134 //at1->print();
Chris@16	1135 //at1->otherTailp_->print();
Chris@16	1136 //std::cout << "test5\n";
Chris@16	1137 //std::cout << "delete " << at1 << "\n";
Chris@16	1138 delete at1;
Chris@16	1139 //std::cout << "test6\n";
Chris@16	1140 return 0;
Chris@16	1141 } else {
Chris@16	1142 //we are closing a hole, return the tail end active tail of the figure
Chris@16	1143 return at1;
Chris@16	1144 }
Chris@16	1145 }
Chris@16	1146 //we are not closing a figure
Chris@16	1147 at1->pushPoint(point);
Chris@16	1148 at1->join(at2);
Chris@16	1149 delete at1;
Chris@16	1150 delete at2;
Chris@16	1151 return 0;
Chris@16	1152 }
Chris@16	1153
Chris@16	1154 inline void destroyContents() {
Chris@16	1155 if(otherTailp_) {
Chris@16	1156 //std::cout << "delete p " << tailp_ << "\n";
Chris@16	1157 if(tailp_) delete tailp_;
Chris@16	1158 tailp_ = 0;
Chris@16	1159 otherTailp_->otherTailp_ = 0;
Chris@16	1160 otherTailp_->tailp_ = 0;
Chris@16	1161 otherTailp_ = 0;
Chris@16	1162 }
Chris@16	1163 for(typename std::list<active_tail_arbitrary*>::iterator itr = holesList_.begin(); itr != holesList_.end(); ++itr) {
Chris@16	1164 //std::cout << "delete p " << (*itr) << "\n";
Chris@16	1165 if(*itr) {
Chris@16	1166 if((*itr)->otherTailp_) {
Chris@16	1167 delete (*itr)->otherTailp_;
Chris@16	1168 (*itr)->otherTailp_ = 0;
Chris@16	1169 }
Chris@16	1170 delete (*itr);
Chris@16	1171 }
Chris@16	1172 (*itr) = 0;
Chris@16	1173 }
Chris@16	1174 holesList_.clear();
Chris@16	1175 }
Chris@16	1176
Chris@16	1177 inline void print() {
Chris@16	1178 //std::cout << this << " " << tailp_ << " " << otherTailp_ << " " << holesList_.size() << " " << head_ << "\n";
Chris@16	1179 }
Chris@16	1180
Chris@16	1181 static inline std::pair<active_tail_arbitrary, active_tail_arbitrary> createActiveTailsAsPair(Point point, bool solid,
Chris@16	1182 active_tail_arbitrary* phole, bool fractureHoles) {
Chris@16	1183 active_tail_arbitrary* at1 = 0;
Chris@16	1184 active_tail_arbitrary* at2 = 0;
Chris@16	1185 if(phole && fractureHoles) {
Chris@16	1186 //std::cout << "adding hole\n";
Chris@16	1187 at1 = phole;
Chris@16	1188 //assert solid == false, we should be creating a corner with solid below and to the left if there was a hole
Chris@16	1189 at2 = at1->getOtherActiveTail();
Chris@16	1190 at2->pushPoint(point);
Chris@16	1191 at1->pushPoint(point);
Chris@16	1192 } else {
Chris@16	1193 at1 = new active_tail_arbitrary(point, at2, solid);
Chris@16	1194 at2 = new active_tail_arbitrary(at1);
Chris@16	1195 at1->otherTailp_ = at2;
Chris@16	1196 at2->head_ = !solid;
Chris@16	1197 if(phole)
Chris@16	1198 at2->addHole(phole); //assert fractureHoles == false
Chris@16	1199 }
Chris@16	1200 return std::pair<active_tail_arbitrary, active_tail_arbitrary>(at1, at2);
Chris@16	1201 }
Chris@16	1202
Chris@16	1203 };
Chris@16	1204
Chris@16	1205
Chris@16	1206 typedef std::vector<std::pair<Point, int> > vertex_arbitrary_count;
Chris@16	1207
Chris@16	1208 class less_half_edge_count : public std::binary_function<vertex_half_edge, vertex_half_edge, bool> {
Chris@16	1209 private:
Chris@16	1210 Point pt_;
Chris@16	1211 public:
Chris@16	1212 inline less_half_edge_count() : pt_() {}
Chris@16	1213 inline less_half_edge_count(Point point) : pt_(point) {}
Chris@16	1214 inline bool operator () (const std::pair<Point, int>& elm1, const std::pair<Point, int>& elm2) const {
Chris@16	1215 return scanline_base<Unit>::less_slope(pt_.get(HORIZONTAL), pt_.get(VERTICAL), elm1.first, elm2.first);
Chris@16	1216 }
Chris@16	1217 };
Chris@16	1218
Chris@16	1219 static inline void sort_vertex_arbitrary_count(vertex_arbitrary_count& count, const Point& pt) {
Chris@16	1220 less_half_edge_count lfec(pt);
Chris@16	1221 polygon_sort(count.begin(), count.end(), lfec);
Chris@16	1222 }
Chris@16	1223
Chris@16	1224 typedef std::vector<std::pair<std::pair<std::pair<Point, Point>, int>, active_tail_arbitrary*> > incoming_count;
Chris@16	1225
Chris@16	1226 class less_incoming_count : public std::binary_function<std::pair<std::pair<std::pair<Point, Point>, int>, active_tail_arbitrary*>,
Chris@16	1227 std::pair<std::pair<std::pair<Point, Point>, int>, active_tail_arbitrary*>, bool> {
Chris@16	1228 private:
Chris@16	1229 Point pt_;
Chris@16	1230 public:
Chris@16	1231 inline less_incoming_count() : pt_() {}
Chris@16	1232 inline less_incoming_count(Point point) : pt_(point) {}
Chris@16	1233 inline bool operator () (const std::pair<std::pair<std::pair<Point, Point>, int>, active_tail_arbitrary*>& elm1,
Chris@16	1234 const std::pair<std::pair<std::pair<Point, Point>, int>, active_tail_arbitrary*>& elm2) const {
Chris@16	1235 Unit dx1 = elm1.first.first.first.get(HORIZONTAL) - elm1.first.first.second.get(HORIZONTAL);
Chris@16	1236 Unit dx2 = elm2.first.first.first.get(HORIZONTAL) - elm2.first.first.second.get(HORIZONTAL);
Chris@16	1237 Unit dy1 = elm1.first.first.first.get(VERTICAL) - elm1.first.first.second.get(VERTICAL);
Chris@16	1238 Unit dy2 = elm2.first.first.first.get(VERTICAL) - elm2.first.first.second.get(VERTICAL);
Chris@16	1239 return scanline_base<Unit>::less_slope(dx1, dy1, dx2, dy2);
Chris@16	1240 }
Chris@16	1241 };
Chris@16	1242
Chris@16	1243 static inline void sort_incoming_count(incoming_count& count, const Point& pt) {
Chris@16	1244 less_incoming_count lfec(pt);
Chris@16	1245 polygon_sort(count.begin(), count.end(), lfec);
Chris@16	1246 }
Chris@16	1247
Chris@16	1248 static inline void compact_vertex_arbitrary_count(const Point& pt, vertex_arbitrary_count &count) {
Chris@16	1249 if(count.empty()) return;
Chris@16	1250 vertex_arbitrary_count tmp;
Chris@16	1251 tmp.reserve(count.size());
Chris@16	1252 tmp.push_back(count[0]);
Chris@16	1253 //merge duplicates
Chris@16	1254 for(std::size_t i = 1; i < count.size(); ++i) {
Chris@16	1255 if(!equal_slope(pt.get(HORIZONTAL), pt.get(VERTICAL), tmp[i-1].first, count[i].first)) {
Chris@16	1256 tmp.push_back(count[i]);
Chris@16	1257 } else {
Chris@16	1258 tmp.back().second += count[i].second;
Chris@16	1259 }
Chris@16	1260 }
Chris@16	1261 count.clear();
Chris@16	1262 count.swap(tmp);
Chris@16	1263 }
Chris@16	1264
Chris@16	1265 // inline std::ostream& operator<< (std::ostream& o, const vertex_arbitrary_count& c) {
Chris@16	1266 // for(unsinged int i = 0; i < c.size(); ++i) {
Chris@16	1267 // o << c[i].first << " " << c[i].second << " ";
Chris@16	1268 // }
Chris@16	1269 // return o;
Chris@16	1270 // }
Chris@16	1271
Chris@16	1272 class vertex_arbitrary_compact {
Chris@16	1273 public:
Chris@16	1274 Point pt;
Chris@16	1275 vertex_arbitrary_count count;
Chris@16	1276 inline vertex_arbitrary_compact() : pt(), count() {}
Chris@16	1277 inline vertex_arbitrary_compact(const Point& point, const Point& other_point, int countIn) : pt(point), count() {
Chris@16	1278 count.push_back(std::pair<Point, int>(other_point, countIn));
Chris@16	1279 }
Chris@16	1280 inline vertex_arbitrary_compact(const vertex_half_edge& vertex) : pt(vertex.pt), count() {
Chris@16	1281 count.push_back(std::pair<Point, int>(vertex.other_pt, vertex.count));
Chris@16	1282 }
Chris@16	1283 inline vertex_arbitrary_compact(const vertex_arbitrary_compact& vertex) : pt(vertex.pt), count(vertex.count) {}
Chris@16	1284 inline vertex_arbitrary_compact& operator=(const vertex_arbitrary_compact& vertex){
Chris@16	1285 pt = vertex.pt; count = vertex.count; return *this; }
Chris@16	1286 //inline vertex_arbitrary_compact(const std::pair<Point, Point>& vertex) {}
Chris@16	1287 inline vertex_arbitrary_compact& operator=(const std::pair<Point, Point>& vertex){ return *this; }
Chris@16	1288 inline bool operator==(const vertex_arbitrary_compact& vertex) const {
Chris@16	1289 return pt == vertex.pt && count == vertex.count; }
Chris@16	1290 inline bool operator!=(const vertex_arbitrary_compact& vertex) const { return !((*this) == vertex); }
Chris@16	1291 inline bool operator==(const std::pair<Point, Point>& vertex) const { return false; }
Chris@16	1292 inline bool operator!=(const std::pair<Point, Point>& vertex) const { return !((*this) == vertex); }
Chris@16	1293 inline bool operator<(const vertex_arbitrary_compact& vertex) const {
Chris@16	1294 if(pt.get(HORIZONTAL) < vertex.pt.get(HORIZONTAL)) return true;
Chris@16	1295 if(pt.get(HORIZONTAL) == vertex.pt.get(HORIZONTAL)) {
Chris@16	1296 return pt.get(VERTICAL) < vertex.pt.get(VERTICAL);
Chris@16	1297 }
Chris@16	1298 return false;
Chris@16	1299 }
Chris@16	1300 inline bool operator>(const vertex_arbitrary_compact& vertex) const { return vertex < (*this); }
Chris@16	1301 inline bool operator<=(const vertex_arbitrary_compact& vertex) const { return !((*this) > vertex); }
Chris@16	1302 inline bool operator>=(const vertex_arbitrary_compact& vertex) const { return !((*this) < vertex); }
Chris@16	1303 inline bool have_vertex_half_edge(int index) const { return count[index]; }
Chris@16	1304 inline vertex_half_edge operator[](int index) const { return vertex_half_edge(pt, count[index]); }
Chris@16	1305 };
Chris@16	1306
Chris@16	1307 // inline std::ostream& operator<< (std::ostream& o, const vertex_arbitrary_compact& c) {
Chris@16	1308 // o << c.pt << ", " << c.count;
Chris@16	1309 // return o;
Chris@16	1310 // }
Chris@16	1311
Chris@16	1312 protected:
Chris@16	1313 //definitions
Chris@16	1314 typedef std::map<vertex_half_edge, active_tail_arbitrary*, less_vertex_half_edge> scanline_data;
Chris@16	1315 typedef typename scanline_data::iterator iterator;
Chris@16	1316 typedef typename scanline_data::const_iterator const_iterator;
Chris@16	1317
Chris@16	1318 //data
Chris@16	1319 scanline_data scanData_;
Chris@16	1320 Unit x_;
Chris@16	1321 int justBefore_;
Chris@16	1322 int fractureHoles_;
Chris@16	1323 public:
Chris@16	1324 inline polygon_arbitrary_formation() :
Chris@16	1325 scanData_(), x_((std::numeric_limits<Unit>::min)()), justBefore_(false), fractureHoles_(0) {
Chris@16	1326 less_vertex_half_edge lessElm(&x_, &justBefore_);
Chris@16	1327 scanData_ = scanline_data(lessElm);
Chris@16	1328 }
Chris@16	1329 inline polygon_arbitrary_formation(bool fractureHoles) :
Chris@16	1330 scanData_(), x_((std::numeric_limits<Unit>::min)()), justBefore_(false), fractureHoles_(fractureHoles) {
Chris@16	1331 less_vertex_half_edge lessElm(&x_, &justBefore_);
Chris@16	1332 scanData_ = scanline_data(lessElm);
Chris@16	1333 }
Chris@16	1334 inline polygon_arbitrary_formation(const polygon_arbitrary_formation& that) :
Chris@16	1335 scanData_(), x_((std::numeric_limits<Unit>::min)()), justBefore_(false), fractureHoles_(0) { (*this) = that; }
Chris@16	1336 inline polygon_arbitrary_formation& operator=(const polygon_arbitrary_formation& that) {
Chris@16	1337 x_ = that.x_;
Chris@16	1338 justBefore_ = that.justBefore_;
Chris@16	1339 fractureHoles_ = that.fractureHoles_;
Chris@16	1340 less_vertex_half_edge lessElm(&x_, &justBefore_);
Chris@16	1341 scanData_ = scanline_data(lessElm);
Chris@16	1342 for(const_iterator itr = that.scanData_.begin(); itr != that.scanData_.end(); ++itr){
Chris@16	1343 scanData_.insert(scanData_.end(), *itr);
Chris@16	1344 }
Chris@16	1345 return *this;
Chris@16	1346 }
Chris@16	1347
Chris@16	1348 //cT is an output container of Polygon45 or Polygon45WithHoles
Chris@16	1349 //iT is an iterator over vertex_half_edge elements
Chris@16	1350 //inputBegin - inputEnd is a range of sorted iT that represents
Chris@16	1351 //one or more scanline stops worth of data
Chris@16	1352 template <class cT, class iT>
Chris@16	1353 void scan(cT& output, iT inputBegin, iT inputEnd) {
Chris@16	1354 //std::cout << "1\n";
Chris@16	1355 while(inputBegin != inputEnd) {
Chris@16	1356 //std::cout << "2\n";
Chris@16	1357 x_ = (*inputBegin).pt.get(HORIZONTAL);
Chris@16	1358 //std::cout << "SCAN FORMATION " << x_ << "\n";
Chris@16	1359 //std::cout << "x_ = " << x_ << "\n";
Chris@16	1360 //std::cout << "scan line size: " << scanData_.size() << "\n";
Chris@16	1361 inputBegin = processEvent_(output, inputBegin, inputEnd);
Chris@16	1362 }
Chris@16	1363 //std::cout << "scan line size: " << scanData_.size() << "\n";
Chris@16	1364 }
Chris@16	1365
Chris@16	1366 protected:
Chris@16	1367 //functions
Chris@16	1368 template <class cT, class cT2>
Chris@16	1369 inline std::pair<std::pair<Point, int>, active_tail_arbitrary*> processPoint_(cT& output, cT2& elements, Point point,
Chris@16	1370 incoming_count& counts_from_scanline, vertex_arbitrary_count& incoming_count) {
Chris@16	1371 //std::cout << "\nAT POINT: " << point << "\n";
Chris@16	1372 //join any closing solid corners
Chris@16	1373 std::vector<int> counts;
Chris@16	1374 std::vector<int> incoming;
Chris@16	1375 std::vector<active_tail_arbitrary*> tails;
Chris@16	1376 counts.reserve(counts_from_scanline.size());
Chris@16	1377 tails.reserve(counts_from_scanline.size());
Chris@16	1378 incoming.reserve(incoming_count.size());
Chris@16	1379 for(std::size_t i = 0; i < counts_from_scanline.size(); ++i) {
Chris@16	1380 counts.push_back(counts_from_scanline[i].first.second);
Chris@16	1381 tails.push_back(counts_from_scanline[i].second);
Chris@16	1382 }
Chris@16	1383 for(std::size_t i = 0; i < incoming_count.size(); ++i) {
Chris@16	1384 incoming.push_back(incoming_count[i].second);
Chris@16	1385 if(incoming_count[i].first < point) {
Chris@16	1386 incoming.back() = 0;
Chris@16	1387 }
Chris@16	1388 }
Chris@16	1389
Chris@16	1390 active_tail_arbitrary* returnValue = 0;
Chris@16	1391 std::pair<Point, int> returnCount(Point(0, 0), 0);
Chris@16	1392 int i_size_less_1 = (int)(incoming.size()) -1;
Chris@16	1393 int c_size_less_1 = (int)(counts.size()) -1;
Chris@16	1394 int i_size = incoming.size();
Chris@16	1395 int c_size = counts.size();
Chris@16	1396
Chris@16	1397 bool have_vertical_tail_from_below = false;
Chris@16	1398 if(c_size &&
Chris@16	1399 scanline_base<Unit>::is_vertical(counts_from_scanline.back().first.first)) {
Chris@16	1400 have_vertical_tail_from_below = true;
Chris@16	1401 }
Chris@16	1402 //assert size = size_less_1 + 1
Chris@16	1403 //std::cout << tails.size() << " " << incoming.size() << " " << counts_from_scanline.size() << " " << incoming_count.size() << "\n";
Chris@16	1404 // for(std::size_t i = 0; i < counts.size(); ++i) {
Chris@16	1405 // std::cout << counts_from_scanline[i].first.first.first.get(HORIZONTAL) << ",";
Chris@16	1406 // std::cout << counts_from_scanline[i].first.first.first.get(VERTICAL) << " ";
Chris@16	1407 // std::cout << counts_from_scanline[i].first.first.second.get(HORIZONTAL) << ",";
Chris@16	1408 // std::cout << counts_from_scanline[i].first.first.second.get(VERTICAL) << ":";
Chris@16	1409 // std::cout << counts_from_scanline[i].first.second << " ";
Chris@16	1410 // } std::cout << "\n";
Chris@16	1411 // print(incoming_count);
Chris@16	1412 {
Chris@16	1413 for(int i = 0; i < c_size_less_1; ++i) {
Chris@16	1414 //std::cout << i << "\n";
Chris@16	1415 if(counts[i] == -1) {
Chris@16	1416 //std::cout << "fixed i\n";
Chris@16	1417 for(int j = i + 1; j < c_size; ++j) {
Chris@16	1418 //std::cout << j << "\n";
Chris@16	1419 if(counts[j]) {
Chris@16	1420 if(counts[j] == 1) {
Chris@16	1421 //std::cout << "case1: " << i << " " << j << "\n";
Chris@16	1422 //if a figure is closed it will be written out by this function to output
Chris@16	1423 active_tail_arbitrary::joinChains(point, tails[i], tails[j], true, output);
Chris@16	1424 counts[i] = 0;
Chris@16	1425 counts[j] = 0;
Chris@16	1426 tails[i] = 0;
Chris@16	1427 tails[j] = 0;
Chris@16	1428 }
Chris@16	1429 break;
Chris@16	1430 }
Chris@16	1431 }
Chris@16	1432 }
Chris@16	1433 }
Chris@16	1434 }
Chris@16	1435 //find any pairs of incoming edges that need to create pair for leading solid
Chris@16	1436 //std::cout << "checking case2\n";
Chris@16	1437 {
Chris@16	1438 for(int i = 0; i < i_size_less_1; ++i) {
Chris@16	1439 //std::cout << i << "\n";
Chris@16	1440 if(incoming[i] == 1) {
Chris@16	1441 //std::cout << "fixed i\n";
Chris@16	1442 for(int j = i + 1; j < i_size; ++j) {
Chris@16	1443 //std::cout << j << "\n";
Chris@16	1444 if(incoming[j]) {
Chris@16	1445 //std::cout << incoming[j] << "\n";
Chris@16	1446 if(incoming[j] == -1) {
Chris@16	1447 //std::cout << "case2: " << i << " " << j << "\n";
Chris@16	1448 //std::cout << "creating active tail pair\n";
Chris@16	1449 std::pair<active_tail_arbitrary, active_tail_arbitrary> tailPair =
Chris@16	1450 active_tail_arbitrary::createActiveTailsAsPair(point, true, 0, fractureHoles_ != 0);
Chris@16	1451 //tailPair.first->print();
Chris@16	1452 //tailPair.second->print();
Chris@16	1453 if(j == i_size_less_1 && incoming_count[j].first.get(HORIZONTAL) == point.get(HORIZONTAL)) {
Chris@16	1454 //vertical active tail becomes return value
Chris@16	1455 returnValue = tailPair.first;
Chris@16	1456 returnCount.first = point;
Chris@16	1457 returnCount.second = 1;
Chris@16	1458 } else {
Chris@16	1459 //std::cout << "new element " << j-1 << " " << -1 << "\n";
Chris@16	1460 //std::cout << point << " " << incoming_count[j].first << "\n";
Chris@16	1461 elements.push_back(std::pair<vertex_half_edge,
Chris@16	1462 active_tail_arbitrary*>(vertex_half_edge(point,
Chris@16	1463 incoming_count[j].first, -1), tailPair.first));
Chris@16	1464 }
Chris@16	1465 //std::cout << "new element " << i-1 << " " << 1 << "\n";
Chris@16	1466 //std::cout << point << " " << incoming_count[i].first << "\n";
Chris@16	1467 elements.push_back(std::pair<vertex_half_edge,
Chris@16	1468 active_tail_arbitrary*>(vertex_half_edge(point,
Chris@16	1469 incoming_count[i].first, 1), tailPair.second));
Chris@16	1470 incoming[i] = 0;
Chris@16	1471 incoming[j] = 0;
Chris@16	1472 }
Chris@16	1473 break;
Chris@16	1474 }
Chris@16	1475 }
Chris@16	1476 }
Chris@16	1477 }
Chris@16	1478 }
Chris@16	1479 //find any active tail that needs to pass through to an incoming edge
Chris@16	1480 //we expect to find no more than two pass through
Chris@16	1481
Chris@16	1482 //find pass through with solid on top
Chris@16	1483 {
Chris@16	1484 //std::cout << "checking case 3\n";
Chris@16	1485 for(int i = 0; i < c_size; ++i) {
Chris@16	1486 //std::cout << i << "\n";
Chris@16	1487 if(counts[i] != 0) {
Chris@16	1488 if(counts[i] == 1) {
Chris@16	1489 //std::cout << "fixed i\n";
Chris@16	1490 for(int j = i_size_less_1; j >= 0; --j) {
Chris@16	1491 if(incoming[j] != 0) {
Chris@16	1492 if(incoming[j] == 1) {
Chris@16	1493 //std::cout << "case3: " << i << " " << j << "\n";
Chris@16	1494 //tails[i]->print();
Chris@16	1495 //pass through solid on top
Chris@16	1496 tails[i]->pushPoint(point);
Chris@16	1497 //std::cout << "after push\n";
Chris@16	1498 if(j == i_size_less_1 && incoming_count[j].first.get(HORIZONTAL) == point.get(HORIZONTAL)) {
Chris@16	1499 returnValue = tails[i];
Chris@16	1500 returnCount.first = point;
Chris@16	1501 returnCount.second = -1;
Chris@16	1502 } else {
Chris@16	1503 elements.push_back(std::pair<vertex_half_edge,
Chris@16	1504 active_tail_arbitrary*>(vertex_half_edge(point,
Chris@16	1505 incoming_count[j].first, incoming[j]), tails[i]));
Chris@16	1506 }
Chris@16	1507 tails[i] = 0;
Chris@16	1508 counts[i] = 0;
Chris@16	1509 incoming[j] = 0;
Chris@16	1510 }
Chris@16	1511 break;
Chris@16	1512 }
Chris@16	1513 }
Chris@16	1514 }
Chris@16	1515 break;
Chris@16	1516 }
Chris@16	1517 }
Chris@16	1518 }
Chris@16	1519 //std::cout << "checking case 4\n";
Chris@16	1520 //find pass through with solid on bottom
Chris@16	1521 {
Chris@16	1522 for(int i = c_size_less_1; i >= 0; --i) {
Chris@16	1523 //std::cout << "i = " << i << " with count " << counts[i] << "\n";
Chris@16	1524 if(counts[i] != 0) {
Chris@16	1525 if(counts[i] == -1) {
Chris@16	1526 for(int j = 0; j < i_size; ++j) {
Chris@16	1527 if(incoming[j] != 0) {
Chris@16	1528 if(incoming[j] == -1) {
Chris@16	1529 //std::cout << "case4: " << i << " " << j << "\n";
Chris@16	1530 //pass through solid on bottom
Chris@16	1531 tails[i]->pushPoint(point);
Chris@16	1532 if(j == i_size_less_1 && incoming_count[j].first.get(HORIZONTAL) == point.get(HORIZONTAL)) {
Chris@16	1533 returnValue = tails[i];
Chris@16	1534 returnCount.first = point;
Chris@16	1535 returnCount.second = 1;
Chris@16	1536 } else {
Chris@16	1537 //std::cout << "new element " << j-1 << " " << incoming[j] << "\n";
Chris@16	1538 //std::cout << point << " " << incoming_count[j].first << "\n";
Chris@16	1539 elements.push_back(std::pair<vertex_half_edge,
Chris@16	1540 active_tail_arbitrary*>(vertex_half_edge(point,
Chris@16	1541 incoming_count[j].first, incoming[j]), tails[i]));
Chris@16	1542 }
Chris@16	1543 tails[i] = 0;
Chris@16	1544 counts[i] = 0;
Chris@16	1545 incoming[j] = 0;
Chris@16	1546 }
Chris@16	1547 break;
Chris@16	1548 }
Chris@16	1549 }
Chris@16	1550 }
Chris@16	1551 break;
Chris@16	1552 }
Chris@16	1553 }
Chris@16	1554 }
Chris@16	1555 //find the end of a hole or the beginning of a hole
Chris@16	1556
Chris@16	1557 //find end of a hole
Chris@16	1558 {
Chris@16	1559 for(int i = 0; i < c_size_less_1; ++i) {
Chris@16	1560 if(counts[i] != 0) {
Chris@16	1561 for(int j = i+1; j < c_size; ++j) {
Chris@16	1562 if(counts[j] != 0) {
Chris@16	1563 //std::cout << "case5: " << i << " " << j << "\n";
Chris@16	1564 //we are ending a hole and may potentially close a figure and have to handle the hole
Chris@16	1565 returnValue = active_tail_arbitrary::joinChains(point, tails[i], tails[j], false, output);
Chris@16	1566 if(returnValue) returnCount.first = point;
Chris@16	1567 //std::cout << returnValue << "\n";
Chris@16	1568 tails[i] = 0;
Chris@16	1569 tails[j] = 0;
Chris@16	1570 counts[i] = 0;
Chris@16	1571 counts[j] = 0;
Chris@16	1572 break;
Chris@16	1573 }
Chris@16	1574 }
Chris@16	1575 break;
Chris@16	1576 }
Chris@16	1577 }
Chris@16	1578 }
Chris@16	1579 //find beginning of a hole
Chris@16	1580 {
Chris@16	1581 for(int i = 0; i < i_size_less_1; ++i) {
Chris@16	1582 if(incoming[i] != 0) {
Chris@16	1583 for(int j = i+1; j < i_size; ++j) {
Chris@16	1584 if(incoming[j] != 0) {
Chris@16	1585 //std::cout << "case6: " << i << " " << j << "\n";
Chris@16	1586 //we are beginning a empty space
Chris@16	1587 active_tail_arbitrary* holep = 0;
Chris@16	1588 //if(c_size && counts[c_size_less_1] == 0 &&
Chris@16	1589 // counts_from_scanline[c_size_less_1].first.first.first.get(HORIZONTAL) == point.get(HORIZONTAL))
Chris@16	1590 if(have_vertical_tail_from_below) {
Chris@16	1591 holep = tails[c_size_less_1];
Chris@16	1592 tails[c_size_less_1] = 0;
Chris@16	1593 have_vertical_tail_from_below = false;
Chris@16	1594 }
Chris@16	1595 std::pair<active_tail_arbitrary, active_tail_arbitrary> tailPair =
Chris@16	1596 active_tail_arbitrary::createActiveTailsAsPair(point, false, holep, fractureHoles_ != 0);
Chris@16	1597 if(j == i_size_less_1 && incoming_count[j].first.get(HORIZONTAL) == point.get(HORIZONTAL)) {
Chris@16	1598 //std::cout << "vertical element " << point << "\n";
Chris@16	1599 returnValue = tailPair.first;
Chris@16	1600 returnCount.first = point;
Chris@16	1601 //returnCount = incoming_count[j];
Chris@16	1602 returnCount.second = -1;
Chris@16	1603 } else {
Chris@16	1604 //std::cout << "new element " << j-1 << " " << incoming[j] << "\n";
Chris@16	1605 //std::cout << point << " " << incoming_count[j].first << "\n";
Chris@16	1606 elements.push_back(std::pair<vertex_half_edge,
Chris@16	1607 active_tail_arbitrary*>(vertex_half_edge(point,
Chris@16	1608 incoming_count[j].first, incoming[j]), tailPair.first));
Chris@16	1609 }
Chris@16	1610 //std::cout << "new element " << i-1 << " " << incoming[i] << "\n";
Chris@16	1611 //std::cout << point << " " << incoming_count[i].first << "\n";
Chris@16	1612 elements.push_back(std::pair<vertex_half_edge,
Chris@16	1613 active_tail_arbitrary*>(vertex_half_edge(point,
Chris@16	1614 incoming_count[i].first, incoming[i]), tailPair.second));
Chris@16	1615 incoming[i] = 0;
Chris@16	1616 incoming[j] = 0;
Chris@16	1617 break;
Chris@16	1618 }
Chris@16	1619 }
Chris@16	1620 break;
Chris@16	1621 }
Chris@16	1622 }
Chris@16	1623 }
Chris@16	1624 if(have_vertical_tail_from_below) {
Chris@16	1625 if(tails.back()) {
Chris@16	1626 tails.back()->pushPoint(point);
Chris@16	1627 returnValue = tails.back();
Chris@16	1628 returnCount.first = point;
Chris@16	1629 returnCount.second = counts.back();
Chris@16	1630 }
Chris@16	1631 }
Chris@16	1632 //assert that tails, counts and incoming are all null
Chris@16	1633 return std::pair<std::pair<Point, int>, active_tail_arbitrary*>(returnCount, returnValue);
Chris@16	1634 }
Chris@16	1635
Chris@16	1636 static inline void print(const vertex_arbitrary_count& count) {
Chris@16	1637 for(unsigned i = 0; i < count.size(); ++i) {
Chris@16	1638 //std::cout << count[i].first.get(HORIZONTAL) << ",";
Chris@16	1639 //std::cout << count[i].first.get(VERTICAL) << ":";
Chris@16	1640 //std::cout << count[i].second << " ";
Chris@16	1641 } //std::cout << "\n";
Chris@16	1642 }
Chris@16	1643
Chris@16	1644 static inline void print(const scanline_data& data) {
Chris@16	1645 for(typename scanline_data::const_iterator itr = data.begin(); itr != data.end(); ++itr){
Chris@16	1646 //std::cout << itr->first.pt << ", " << itr->first.other_pt << "; ";
Chris@16	1647 } //std::cout << "\n";
Chris@16	1648 }
Chris@16	1649
Chris@16	1650 template <class cT, class iT>
Chris@16	1651 inline iT processEvent_(cT& output, iT inputBegin, iT inputEnd) {
Chris@16	1652 typedef typename high_precision_type<Unit>::type high_precision;
Chris@16	1653 //std::cout << "processEvent_\n";
Chris@16	1654 justBefore_ = true;
Chris@16	1655 //collect up all elements from the tree that are at the y
Chris@16	1656 //values of events in the input queue
Chris@16	1657 //create vector of new elements to add into tree
Chris@16	1658 active_tail_arbitrary* verticalTail = 0;
Chris@16	1659 std::pair<Point, int> verticalCount(Point(0, 0), 0);
Chris@16	1660 iT currentIter = inputBegin;
Chris@16	1661 std::vector<iterator> elementIters;
Chris@16	1662 std::vector<std::pair<vertex_half_edge, active_tail_arbitrary*> > elements;
Chris@16	1663 while(currentIter != inputEnd && currentIter->pt.get(HORIZONTAL) == x_) {
Chris@16	1664 //std::cout << "loop\n";
Chris@16	1665 Unit currentY = (*currentIter).pt.get(VERTICAL);
Chris@16	1666 //std::cout << "current Y " << currentY << "\n";
Chris@16	1667 //std::cout << "scanline size " << scanData_.size() << "\n";
Chris@16	1668 //print(scanData_);
Chris@16	1669 iterator iter = lookUp_(currentY);
Chris@16	1670 //std::cout << "found element in scanline " << (iter != scanData_.end()) << "\n";
Chris@16	1671 //int counts[4] = {0, 0, 0, 0};
Chris@16	1672 incoming_count counts_from_scanline;
Chris@16	1673 //std::cout << "finding elements in tree\n";
Chris@16	1674 //if(iter != scanData_.end())
Chris@16	1675 // std::cout << "first iter y is " << iter->first.evalAtX(x_) << "\n";
Chris@16	1676 while(iter != scanData_.end() &&
Chris@16	1677 ((iter->first.pt.x() == x_ && iter->first.pt.y() == currentY) \|\|
Chris@16	1678 (iter->first.other_pt.x() == x_ && iter->first.other_pt.y() == currentY))) {
Chris@16	1679 //iter->first.evalAtX(x_) == (high_precision)currentY) {
Chris@16	1680 //std::cout << "loop2\n";
Chris@16	1681 elementIters.push_back(iter);
Chris@16	1682 counts_from_scanline.push_back(std::pair<std::pair<std::pair<Point, Point>, int>, active_tail_arbitrary*>
Chris@16	1683 (std::pair<std::pair<Point, Point>, int>(std::pair<Point, Point>(iter->first.pt,
Chris@16	1684 iter->first.other_pt),
Chris@16	1685 iter->first.count),
Chris@16	1686 iter->second));
Chris@16	1687 ++iter;
Chris@16	1688 }
Chris@16	1689 Point currentPoint(x_, currentY);
Chris@16	1690 //std::cout << "counts_from_scanline size " << counts_from_scanline.size() << "\n";
Chris@16	1691 sort_incoming_count(counts_from_scanline, currentPoint);
Chris@16	1692
Chris@16	1693 vertex_arbitrary_count incoming;
Chris@16	1694 //std::cout << "aggregating\n";
Chris@16	1695 do {
Chris@16	1696 //std::cout << "loop3\n";
Chris@16	1697 const vertex_half_edge& elem = *currentIter;
Chris@16	1698 incoming.push_back(std::pair<Point, int>(elem.other_pt, elem.count));
Chris@16	1699 ++currentIter;
Chris@16	1700 } while(currentIter != inputEnd && currentIter->pt.get(VERTICAL) == currentY &&
Chris@16	1701 currentIter->pt.get(HORIZONTAL) == x_);
Chris@16	1702 //print(incoming);
Chris@16	1703 sort_vertex_arbitrary_count(incoming, currentPoint);
Chris@16	1704 //std::cout << currentPoint.get(HORIZONTAL) << "," << currentPoint.get(VERTICAL) << "\n";
Chris@16	1705 //print(incoming);
Chris@16	1706 //std::cout << "incoming counts from input size " << incoming.size() << "\n";
Chris@16	1707 //compact_vertex_arbitrary_count(currentPoint, incoming);
Chris@16	1708 vertex_arbitrary_count tmp;
Chris@16	1709 tmp.reserve(incoming.size());
Chris@16	1710 for(std::size_t i = 0; i < incoming.size(); ++i) {
Chris@16	1711 if(currentPoint < incoming[i].first) {
Chris@16	1712 tmp.push_back(incoming[i]);
Chris@16	1713 }
Chris@16	1714 }
Chris@16	1715 incoming.swap(tmp);
Chris@16	1716 //std::cout << "incoming counts from input size " << incoming.size() << "\n";
Chris@16	1717 //now counts_from_scanline has the data from the left and
Chris@16	1718 //incoming has the data from the right at this point
Chris@16	1719 //cancel out any end points
Chris@16	1720 if(verticalTail) {
Chris@16	1721 //std::cout << "adding vertical tail to counts from scanline\n";
Chris@16	1722 //std::cout << -verticalCount.second << "\n";
Chris@16	1723 counts_from_scanline.push_back(std::pair<std::pair<std::pair<Point, Point>, int>, active_tail_arbitrary*>
Chris@16	1724 (std::pair<std::pair<Point, Point>, int>(std::pair<Point, Point>(verticalCount.first,
Chris@16	1725 currentPoint),
Chris@16	1726 -verticalCount.second),
Chris@16	1727 verticalTail));
Chris@16	1728 }
Chris@16	1729 if(!incoming.empty() && incoming.back().first.get(HORIZONTAL) == x_) {
Chris@16	1730 //std::cout << "inverted vertical event\n";
Chris@16	1731 incoming.back().second *= -1;
Chris@16	1732 }
Chris@16	1733 //std::cout << "calling processPoint_\n";
Chris@16	1734 std::pair<std::pair<Point, int>, active_tail_arbitrary*> result = processPoint_(output, elements, Point(x_, currentY), counts_from_scanline, incoming);
Chris@16	1735 verticalCount = result.first;
Chris@16	1736 verticalTail = result.second;
Chris@16	1737 //if(verticalTail) {
Chris@16	1738 // std::cout << "have vertical tail\n";
Chris@16	1739 // std::cout << verticalCount.second << "\n";
Chris@16	1740 //}
Chris@16	1741 if(verticalTail && !(verticalCount.second)) {
Chris@16	1742 //we got a hole out of the point we just processed
Chris@16	1743 //iter is still at the next y element above the current y value in the tree
Chris@16	1744 //std::cout << "checking whether ot handle hole\n";
Chris@16	1745 if(currentIter == inputEnd \|\|
Chris@16	1746 currentIter->pt.get(HORIZONTAL) != x_ \|\|
Chris@16	1747 scanline_base<Unit>::on_above_or_below(currentIter->pt, half_edge(iter->first.pt, iter->first.other_pt)) != -1) {
Chris@16	1748 //(high_precision)(currentIter->pt.get(VERTICAL)) >= iter->first.evalAtX(x_)) {
Chris@16	1749
Chris@16	1750 //std::cout << "handle hole here\n";
Chris@16	1751 if(fractureHoles_) {
Chris@16	1752 //std::cout << "fracture hole here\n";
Chris@16	1753 //we need to handle the hole now and not at the next input vertex
Chris@16	1754 active_tail_arbitrary* at = iter->second;
Chris@16	1755 high_precision precise_y = iter->first.evalAtX(x_);
Chris@16	1756 Unit fracture_y = convert_high_precision_type<Unit>(precise_y);
Chris@16	1757 if(precise_y < fracture_y) --fracture_y;
Chris@16	1758 Point point(x_, fracture_y);
Chris@16	1759 verticalTail->getOtherActiveTail()->pushPoint(point);
Chris@16	1760 iter->second = verticalTail->getOtherActiveTail();
Chris@16	1761 at->pushPoint(point);
Chris@16	1762 verticalTail->join(at);
Chris@16	1763 delete at;
Chris@16	1764 delete verticalTail;
Chris@16	1765 verticalTail = 0;
Chris@16	1766 } else {
Chris@16	1767 //std::cout << "push hole onto list\n";
Chris@16	1768 iter->second->addHole(verticalTail);
Chris@16	1769 verticalTail = 0;
Chris@16	1770 }
Chris@16	1771 }
Chris@16	1772 }
Chris@16	1773 }
Chris@16	1774 //std::cout << "erasing\n";
Chris@16	1775 //erase all elements from the tree
Chris@16	1776 for(typename std::vector<iterator>::iterator iter = elementIters.begin();
Chris@16	1777 iter != elementIters.end(); ++iter) {
Chris@16	1778 //std::cout << "erasing loop\n";
Chris@16	1779 scanData_.erase(*iter);
Chris@16	1780 }
Chris@16	1781 //switch comparison tie breaking policy
Chris@16	1782 justBefore_ = false;
Chris@16	1783 //add new elements into tree
Chris@16	1784 //std::cout << "inserting\n";
Chris@16	1785 for(typename std::vector<std::pair<vertex_half_edge, active_tail_arbitrary*> >::iterator iter = elements.begin();
Chris@16	1786 iter != elements.end(); ++iter) {
Chris@16	1787 //std::cout << "inserting loop\n";
Chris@16	1788 scanData_.insert(scanData_.end(), *iter);
Chris@16	1789 }
Chris@16	1790 //std::cout << "end processEvent\n";
Chris@16	1791 return currentIter;
Chris@16	1792 }
Chris@16	1793
Chris@16	1794 inline iterator lookUp_(Unit y){
Chris@16	1795 //if just before then we need to look from 1 not -1
Chris@16	1796 //std::cout << "just before " << justBefore_ << "\n";
Chris@16	1797 return scanData_.lower_bound(vertex_half_edge(Point(x_, y), Point(x_, y+1), 0));
Chris@16	1798 }
Chris@16	1799
Chris@16	1800 public: //test functions
Chris@16	1801
Chris@16	1802 template <typename stream_type>
Chris@16	1803 static inline bool testPolygonArbitraryFormationRect(stream_type& stdcout) {
Chris@16	1804 stdcout << "testing polygon formation\n";
Chris@16	1805 polygon_arbitrary_formation pf(true);
Chris@16	1806 std::vector<polygon_data<Unit> > polys;
Chris@16	1807 std::vector<vertex_half_edge> data;
Chris@16	1808 data.push_back(vertex_half_edge(Point(0, 0), Point(10, 0), 1));
Chris@16	1809 data.push_back(vertex_half_edge(Point(0, 0), Point(0, 10), 1));
Chris@16	1810 data.push_back(vertex_half_edge(Point(0, 10), Point(0, 0), -1));
Chris@16	1811 data.push_back(vertex_half_edge(Point(0, 10), Point(10, 10), -1));
Chris@16	1812 data.push_back(vertex_half_edge(Point(10, 0), Point(0, 0), -1));
Chris@16	1813 data.push_back(vertex_half_edge(Point(10, 0), Point(10, 10), -1));
Chris@16	1814 data.push_back(vertex_half_edge(Point(10, 10), Point(10, 0), 1));
Chris@16	1815 data.push_back(vertex_half_edge(Point(10, 10), Point(0, 10), 1));
Chris@16	1816 polygon_sort(data.begin(), data.end());
Chris@16	1817 pf.scan(polys, data.begin(), data.end());
Chris@16	1818 stdcout << "result size: " << polys.size() << "\n";
Chris@16	1819 for(std::size_t i = 0; i < polys.size(); ++i) {
Chris@16	1820 stdcout << polys[i] << "\n";
Chris@16	1821 }
Chris@16	1822 stdcout << "done testing polygon formation\n";
Chris@16	1823 return true;
Chris@16	1824 }
Chris@16	1825
Chris@16	1826 template <typename stream_type>
Chris@16	1827 static inline bool testPolygonArbitraryFormationP1(stream_type& stdcout) {
Chris@16	1828 stdcout << "testing polygon formation P1\n";
Chris@16	1829 polygon_arbitrary_formation pf(true);
Chris@16	1830 std::vector<polygon_data<Unit> > polys;
Chris@16	1831 std::vector<vertex_half_edge> data;
Chris@16	1832 data.push_back(vertex_half_edge(Point(0, 0), Point(10, 10), 1));
Chris@16	1833 data.push_back(vertex_half_edge(Point(0, 0), Point(0, 10), 1));
Chris@16	1834 data.push_back(vertex_half_edge(Point(0, 10), Point(0, 0), -1));
Chris@16	1835 data.push_back(vertex_half_edge(Point(0, 10), Point(10, 20), -1));
Chris@16	1836 data.push_back(vertex_half_edge(Point(10, 10), Point(0, 0), -1));
Chris@16	1837 data.push_back(vertex_half_edge(Point(10, 10), Point(10, 20), -1));
Chris@16	1838 data.push_back(vertex_half_edge(Point(10, 20), Point(10, 10), 1));
Chris@16	1839 data.push_back(vertex_half_edge(Point(10, 20), Point(0, 10), 1));
Chris@16	1840 polygon_sort(data.begin(), data.end());
Chris@16	1841 pf.scan(polys, data.begin(), data.end());
Chris@16	1842 stdcout << "result size: " << polys.size() << "\n";
Chris@16	1843 for(std::size_t i = 0; i < polys.size(); ++i) {
Chris@16	1844 stdcout << polys[i] << "\n";
Chris@16	1845 }
Chris@16	1846 stdcout << "done testing polygon formation\n";
Chris@16	1847 return true;
Chris@16	1848 }
Chris@16	1849
Chris@16	1850 template <typename stream_type>
Chris@16	1851 static inline bool testPolygonArbitraryFormationP2(stream_type& stdcout) {
Chris@16	1852 stdcout << "testing polygon formation P2\n";
Chris@16	1853 polygon_arbitrary_formation pf(true);
Chris@16	1854 std::vector<polygon_data<Unit> > polys;
Chris@16	1855 std::vector<vertex_half_edge> data;
Chris@16	1856 data.push_back(vertex_half_edge(Point(-3, 1), Point(2, -4), 1));
Chris@16	1857 data.push_back(vertex_half_edge(Point(-3, 1), Point(-2, 2), -1));
Chris@16	1858 data.push_back(vertex_half_edge(Point(-2, 2), Point(2, 4), -1));
Chris@16	1859 data.push_back(vertex_half_edge(Point(-2, 2), Point(-3, 1), 1));
Chris@16	1860 data.push_back(vertex_half_edge(Point(2, -4), Point(-3, 1), -1));
Chris@16	1861 data.push_back(vertex_half_edge(Point(2, -4), Point(2, 4), -1));
Chris@16	1862 data.push_back(vertex_half_edge(Point(2, 4), Point(-2, 2), 1));
Chris@16	1863 data.push_back(vertex_half_edge(Point(2, 4), Point(2, -4), 1));
Chris@16	1864 polygon_sort(data.begin(), data.end());
Chris@16	1865 pf.scan(polys, data.begin(), data.end());
Chris@16	1866 stdcout << "result size: " << polys.size() << "\n";
Chris@16	1867 for(std::size_t i = 0; i < polys.size(); ++i) {
Chris@16	1868 stdcout << polys[i] << "\n";
Chris@16	1869 }
Chris@16	1870 stdcout << "done testing polygon formation\n";
Chris@16	1871 return true;
Chris@16	1872 }
Chris@16	1873
Chris@16	1874
Chris@16	1875 template <typename stream_type>
Chris@16	1876 static inline bool testPolygonArbitraryFormationPolys(stream_type& stdcout) {
Chris@16	1877 stdcout << "testing polygon formation polys\n";
Chris@16	1878 polygon_arbitrary_formation pf(false);
Chris@16	1879 std::vector<polygon_with_holes_data<Unit> > polys;
Chris@16	1880 polygon_arbitrary_formation pf2(true);
Chris@16	1881 std::vector<polygon_with_holes_data<Unit> > polys2;
Chris@16	1882 std::vector<vertex_half_edge> data;
Chris@16	1883 data.push_back(vertex_half_edge(Point(0, 0), Point(100, 1), 1));
Chris@16	1884 data.push_back(vertex_half_edge(Point(0, 0), Point(1, 100), -1));
Chris@16	1885 data.push_back(vertex_half_edge(Point(1, 100), Point(0, 0), 1));
Chris@16	1886 data.push_back(vertex_half_edge(Point(1, 100), Point(101, 101), -1));
Chris@16	1887 data.push_back(vertex_half_edge(Point(100, 1), Point(0, 0), -1));
Chris@16	1888 data.push_back(vertex_half_edge(Point(100, 1), Point(101, 101), 1));
Chris@16	1889 data.push_back(vertex_half_edge(Point(101, 101), Point(100, 1), -1));
Chris@16	1890 data.push_back(vertex_half_edge(Point(101, 101), Point(1, 100), 1));
Chris@16	1891
Chris@16	1892 data.push_back(vertex_half_edge(Point(2, 2), Point(10, 2), -1));
Chris@16	1893 data.push_back(vertex_half_edge(Point(2, 2), Point(2, 10), -1));
Chris@16	1894 data.push_back(vertex_half_edge(Point(2, 10), Point(2, 2), 1));
Chris@16	1895 data.push_back(vertex_half_edge(Point(2, 10), Point(10, 10), 1));
Chris@16	1896 data.push_back(vertex_half_edge(Point(10, 2), Point(2, 2), 1));
Chris@16	1897 data.push_back(vertex_half_edge(Point(10, 2), Point(10, 10), 1));
Chris@16	1898 data.push_back(vertex_half_edge(Point(10, 10), Point(10, 2), -1));
Chris@16	1899 data.push_back(vertex_half_edge(Point(10, 10), Point(2, 10), -1));
Chris@16	1900
Chris@16	1901 data.push_back(vertex_half_edge(Point(2, 12), Point(10, 12), -1));
Chris@16	1902 data.push_back(vertex_half_edge(Point(2, 12), Point(2, 22), -1));
Chris@16	1903 data.push_back(vertex_half_edge(Point(2, 22), Point(2, 12), 1));
Chris@16	1904 data.push_back(vertex_half_edge(Point(2, 22), Point(10, 22), 1));
Chris@16	1905 data.push_back(vertex_half_edge(Point(10, 12), Point(2, 12), 1));
Chris@16	1906 data.push_back(vertex_half_edge(Point(10, 12), Point(10, 22), 1));
Chris@16	1907 data.push_back(vertex_half_edge(Point(10, 22), Point(10, 12), -1));
Chris@16	1908 data.push_back(vertex_half_edge(Point(10, 22), Point(2, 22), -1));
Chris@16	1909
Chris@16	1910 polygon_sort(data.begin(), data.end());
Chris@16	1911 pf.scan(polys, data.begin(), data.end());
Chris@16	1912 stdcout << "result size: " << polys.size() << "\n";
Chris@16	1913 for(std::size_t i = 0; i < polys.size(); ++i) {
Chris@16	1914 stdcout << polys[i] << "\n";
Chris@16	1915 }
Chris@16	1916 pf2.scan(polys2, data.begin(), data.end());
Chris@16	1917 stdcout << "result size: " << polys2.size() << "\n";
Chris@16	1918 for(std::size_t i = 0; i < polys2.size(); ++i) {
Chris@16	1919 stdcout << polys2[i] << "\n";
Chris@16	1920 }
Chris@16	1921 stdcout << "done testing polygon formation\n";
Chris@16	1922 return true;
Chris@16	1923 }
Chris@16	1924
Chris@16	1925 template <typename stream_type>
Chris@16	1926 static inline bool testPolygonArbitraryFormationSelfTouch1(stream_type& stdcout) {
Chris@16	1927 stdcout << "testing polygon formation self touch 1\n";
Chris@16	1928 polygon_arbitrary_formation pf(true);
Chris@16	1929 std::vector<polygon_data<Unit> > polys;
Chris@16	1930 std::vector<vertex_half_edge> data;
Chris@16	1931 data.push_back(vertex_half_edge(Point(0, 0), Point(10, 0), 1));
Chris@16	1932 data.push_back(vertex_half_edge(Point(0, 0), Point(0, 10), 1));
Chris@16	1933
Chris@16	1934 data.push_back(vertex_half_edge(Point(0, 10), Point(0, 0), -1));
Chris@16	1935 data.push_back(vertex_half_edge(Point(0, 10), Point(5, 10), -1));
Chris@16	1936
Chris@16	1937 data.push_back(vertex_half_edge(Point(10, 0), Point(0, 0), -1));
Chris@16	1938 data.push_back(vertex_half_edge(Point(10, 0), Point(10, 5), -1));
Chris@16	1939
Chris@16	1940 data.push_back(vertex_half_edge(Point(10, 5), Point(10, 0), 1));
Chris@16	1941 data.push_back(vertex_half_edge(Point(10, 5), Point(5, 5), 1));
Chris@16	1942
Chris@16	1943 data.push_back(vertex_half_edge(Point(5, 10), Point(5, 5), 1));
Chris@16	1944 data.push_back(vertex_half_edge(Point(5, 10), Point(0, 10), 1));
Chris@16	1945
Chris@16	1946 data.push_back(vertex_half_edge(Point(5, 2), Point(5, 5), -1));
Chris@16	1947 data.push_back(vertex_half_edge(Point(5, 2), Point(7, 2), -1));
Chris@16	1948
Chris@16	1949 data.push_back(vertex_half_edge(Point(5, 5), Point(5, 10), -1));
Chris@16	1950 data.push_back(vertex_half_edge(Point(5, 5), Point(5, 2), 1));
Chris@16	1951 data.push_back(vertex_half_edge(Point(5, 5), Point(10, 5), -1));
Chris@16	1952 data.push_back(vertex_half_edge(Point(5, 5), Point(7, 2), 1));
Chris@16	1953
Chris@16	1954 data.push_back(vertex_half_edge(Point(7, 2), Point(5, 5), -1));
Chris@16	1955 data.push_back(vertex_half_edge(Point(7, 2), Point(5, 2), 1));
Chris@16	1956
Chris@16	1957 polygon_sort(data.begin(), data.end());
Chris@16	1958 pf.scan(polys, data.begin(), data.end());
Chris@16	1959 stdcout << "result size: " << polys.size() << "\n";
Chris@16	1960 for(std::size_t i = 0; i < polys.size(); ++i) {
Chris@16	1961 stdcout << polys[i] << "\n";
Chris@16	1962 }
Chris@16	1963 stdcout << "done testing polygon formation\n";
Chris@16	1964 return true;
Chris@16	1965 }
Chris@16	1966
Chris@16	1967 template <typename stream_type>
Chris@16	1968 static inline bool testPolygonArbitraryFormationSelfTouch2(stream_type& stdcout) {
Chris@16	1969 stdcout << "testing polygon formation self touch 2\n";
Chris@16	1970 polygon_arbitrary_formation pf(true);
Chris@16	1971 std::vector<polygon_data<Unit> > polys;
Chris@16	1972 std::vector<vertex_half_edge> data;
Chris@16	1973 data.push_back(vertex_half_edge(Point(0, 0), Point(10, 0), 1));
Chris@16	1974 data.push_back(vertex_half_edge(Point(0, 0), Point(0, 10), 1));
Chris@16	1975
Chris@16	1976 data.push_back(vertex_half_edge(Point(0, 10), Point(0, 0), -1));
Chris@16	1977 data.push_back(vertex_half_edge(Point(0, 10), Point(5, 10), -1));
Chris@16	1978
Chris@16	1979 data.push_back(vertex_half_edge(Point(10, 0), Point(0, 0), -1));
Chris@16	1980 data.push_back(vertex_half_edge(Point(10, 0), Point(10, 5), -1));
Chris@16	1981
Chris@16	1982 data.push_back(vertex_half_edge(Point(10, 5), Point(10, 0), 1));
Chris@16	1983 data.push_back(vertex_half_edge(Point(10, 5), Point(5, 5), 1));
Chris@16	1984
Chris@16	1985 data.push_back(vertex_half_edge(Point(5, 10), Point(4, 1), -1));
Chris@16	1986 data.push_back(vertex_half_edge(Point(5, 10), Point(0, 10), 1));
Chris@16	1987
Chris@16	1988 data.push_back(vertex_half_edge(Point(4, 1), Point(5, 10), 1));
Chris@16	1989 data.push_back(vertex_half_edge(Point(4, 1), Point(7, 2), -1));
Chris@16	1990
Chris@16	1991 data.push_back(vertex_half_edge(Point(5, 5), Point(10, 5), -1));
Chris@16	1992 data.push_back(vertex_half_edge(Point(5, 5), Point(7, 2), 1));
Chris@16	1993
Chris@16	1994 data.push_back(vertex_half_edge(Point(7, 2), Point(5, 5), -1));
Chris@16	1995 data.push_back(vertex_half_edge(Point(7, 2), Point(4, 1), 1));
Chris@16	1996
Chris@16	1997 polygon_sort(data.begin(), data.end());
Chris@16	1998 pf.scan(polys, data.begin(), data.end());
Chris@16	1999 stdcout << "result size: " << polys.size() << "\n";
Chris@16	2000 for(std::size_t i = 0; i < polys.size(); ++i) {
Chris@16	2001 stdcout << polys[i] << "\n";
Chris@16	2002 }
Chris@16	2003 stdcout << "done testing polygon formation\n";
Chris@16	2004 return true;
Chris@16	2005 }
Chris@16	2006
Chris@16	2007 template <typename stream_type>
Chris@16	2008 static inline bool testPolygonArbitraryFormationSelfTouch3(stream_type& stdcout) {
Chris@16	2009 stdcout << "testing polygon formation self touch 3\n";
Chris@16	2010 polygon_arbitrary_formation pf(true);
Chris@16	2011 std::vector<polygon_data<Unit> > polys;
Chris@16	2012 std::vector<vertex_half_edge> data;
Chris@16	2013 data.push_back(vertex_half_edge(Point(0, 0), Point(10, 0), 1));
Chris@16	2014 data.push_back(vertex_half_edge(Point(0, 0), Point(0, 10), 1));
Chris@16	2015
Chris@16	2016 data.push_back(vertex_half_edge(Point(0, 10), Point(0, 0), -1));
Chris@16	2017 data.push_back(vertex_half_edge(Point(0, 10), Point(6, 10), -1));
Chris@16	2018
Chris@16	2019 data.push_back(vertex_half_edge(Point(10, 0), Point(0, 0), -1));
Chris@16	2020 data.push_back(vertex_half_edge(Point(10, 0), Point(10, 5), -1));
Chris@16	2021
Chris@16	2022 data.push_back(vertex_half_edge(Point(10, 5), Point(10, 0), 1));
Chris@16	2023 data.push_back(vertex_half_edge(Point(10, 5), Point(5, 5), 1));
Chris@16	2024
Chris@16	2025 data.push_back(vertex_half_edge(Point(6, 10), Point(4, 1), -1));
Chris@16	2026 data.push_back(vertex_half_edge(Point(6, 10), Point(0, 10), 1));
Chris@16	2027
Chris@16	2028 data.push_back(vertex_half_edge(Point(4, 1), Point(6, 10), 1));
Chris@16	2029 data.push_back(vertex_half_edge(Point(4, 1), Point(7, 2), -1));
Chris@16	2030
Chris@16	2031 data.push_back(vertex_half_edge(Point(5, 5), Point(10, 5), -1));
Chris@16	2032 data.push_back(vertex_half_edge(Point(5, 5), Point(7, 2), 1));
Chris@16	2033
Chris@16	2034 data.push_back(vertex_half_edge(Point(7, 2), Point(5, 5), -1));
Chris@16	2035 data.push_back(vertex_half_edge(Point(7, 2), Point(4, 1), 1));
Chris@16	2036
Chris@16	2037 polygon_sort(data.begin(), data.end());
Chris@16	2038 pf.scan(polys, data.begin(), data.end());
Chris@16	2039 stdcout << "result size: " << polys.size() << "\n";
Chris@16	2040 for(std::size_t i = 0; i < polys.size(); ++i) {
Chris@16	2041 stdcout << polys[i] << "\n";
Chris@16	2042 }
Chris@16	2043 stdcout << "done testing polygon formation\n";
Chris@16	2044 return true;
Chris@16	2045 }
Chris@16	2046
Chris@16	2047 template <typename stream_type>
Chris@16	2048 static inline bool testPolygonArbitraryFormationColinear(stream_type& stdcout) {
Chris@16	2049 stdcout << "testing polygon formation colinear 3\n";
Chris@16	2050 stdcout << "Polygon Set Data { <-3 2, -2 2>:1 <-3 2, -1 4>:-1 <-2 2, 0 2>:1 <-1 4, 0 2>:-1 } \n";
Chris@16	2051 polygon_arbitrary_formation pf(true);
Chris@16	2052 std::vector<polygon_data<Unit> > polys;
Chris@16	2053 std::vector<vertex_half_edge> data;
Chris@16	2054 data.push_back(vertex_half_edge(Point(-3, 2), Point(-2, 2), 1));
Chris@16	2055 data.push_back(vertex_half_edge(Point(-2, 2), Point(-3, 2), -1));
Chris@16	2056
Chris@16	2057 data.push_back(vertex_half_edge(Point(-3, 2), Point(-1, 4), -1));
Chris@16	2058 data.push_back(vertex_half_edge(Point(-1, 4), Point(-3, 2), 1));
Chris@16	2059
Chris@16	2060 data.push_back(vertex_half_edge(Point(-2, 2), Point(0, 2), 1));
Chris@16	2061 data.push_back(vertex_half_edge(Point(0, 2), Point(-2, 2), -1));
Chris@16	2062
Chris@16	2063 data.push_back(vertex_half_edge(Point(-1, 4), Point(0, 2), -1));
Chris@16	2064 data.push_back(vertex_half_edge(Point(0, 2), Point(-1, 4), 1));
Chris@16	2065 polygon_sort(data.begin(), data.end());
Chris@16	2066 pf.scan(polys, data.begin(), data.end());
Chris@16	2067 stdcout << "result size: " << polys.size() << "\n";
Chris@16	2068 for(std::size_t i = 0; i < polys.size(); ++i) {
Chris@16	2069 stdcout << polys[i] << "\n";
Chris@16	2070 }
Chris@16	2071 stdcout << "done testing polygon formation\n";
Chris@16	2072 return true;
Chris@16	2073 }
Chris@16	2074
Chris@16	2075 template <typename stream_type>
Chris@16	2076 static inline bool testSegmentIntersection(stream_type& stdcout) {
Chris@16	2077 stdcout << "testing segment intersection\n";
Chris@16	2078 half_edge he1, he2;
Chris@16	2079 he1.first = Point(0, 0);
Chris@16	2080 he1.second = Point(10, 10);
Chris@16	2081 he2.first = Point(0, 0);
Chris@16	2082 he2.second = Point(10, 20);
Chris@16	2083 Point result;
Chris@16	2084 bool b = scanline_base<Unit>::compute_intersection(result, he1, he2);
Chris@16	2085 if(!b \|\| result != Point(0, 0)) return false;
Chris@16	2086 he1.first = Point(0, 10);
Chris@16	2087 b = scanline_base<Unit>::compute_intersection(result, he1, he2);
Chris@16	2088 if(!b \|\| result != Point(5, 10)) return false;
Chris@16	2089 he1.first = Point(0, 11);
Chris@16	2090 b = scanline_base<Unit>::compute_intersection(result, he1, he2);
Chris@16	2091 if(!b \|\| result != Point(5, 10)) return false;
Chris@16	2092 he1.first = Point(0, 0);
Chris@16	2093 he1.second = Point(1, 9);
Chris@16	2094 he2.first = Point(0, 9);
Chris@16	2095 he2.second = Point(1, 0);
Chris@16	2096 b = scanline_base<Unit>::compute_intersection(result, he1, he2);
Chris@16	2097 if(!b \|\| result != Point(0, 4)) return false;
Chris@16	2098
Chris@16	2099 he1.first = Point(0, -10);
Chris@16	2100 he1.second = Point(1, -1);
Chris@16	2101 he2.first = Point(0, -1);
Chris@16	2102 he2.second = Point(1, -10);
Chris@16	2103 b = scanline_base<Unit>::compute_intersection(result, he1, he2);
Chris@16	2104 if(!b \|\| result != Point(0, -5)) return false;
Chris@16	2105 he1.first = Point((std::numeric_limits<int>::max)(), (std::numeric_limits<int>::max)()-1);
Chris@16	2106 he1.second = Point((std::numeric_limits<int>::min)(), (std::numeric_limits<int>::max)());
Chris@16	2107 //he1.second = Point(0, (std::numeric_limits<int>::max)());
Chris@16	2108 he2.first = Point((std::numeric_limits<int>::max)()-1, (std::numeric_limits<int>::max)());
Chris@16	2109 he2.second = Point((std::numeric_limits<int>::max)(), (std::numeric_limits<int>::min)());
Chris@16	2110 //he2.second = Point((std::numeric_limits<int>::max)(), 0);
Chris@16	2111 b = scanline_base<Unit>::compute_intersection(result, he1, he2);
Chris@16	2112 //b is false because of overflow error
Chris@16	2113 he1.first = Point(1000, 2000);
Chris@16	2114 he1.second = Point(1010, 2010);
Chris@16	2115 he2.first = Point(1000, 2000);
Chris@16	2116 he2.second = Point(1010, 2020);
Chris@16	2117 b = scanline_base<Unit>::compute_intersection(result, he1, he2);
Chris@16	2118 if(!b \|\| result != Point(1000, 2000)) return false;
Chris@16	2119
Chris@16	2120 return b;
Chris@16	2121 }
Chris@16	2122
Chris@16	2123 };
Chris@16	2124
Chris@16	2125 template <typename Unit>
Chris@16	2126 class poly_line_arbitrary_hole_data {
Chris@16	2127 private:
Chris@16	2128 typedef typename polygon_arbitrary_formation<Unit>::active_tail_arbitrary active_tail_arbitrary;
Chris@16	2129 active_tail_arbitrary* p_;
Chris@16	2130 public:
Chris@16	2131 typedef point_data<Unit> Point;
Chris@16	2132 typedef Point point_type;
Chris@16	2133 typedef Unit coordinate_type;
Chris@16	2134 typedef typename active_tail_arbitrary::iterator iterator_type;
Chris@16	2135 //typedef iterator_points_to_compact<iterator_type, Point> compact_iterator_type;
Chris@16	2136
Chris@16	2137 typedef iterator_type iterator;
Chris@16	2138 inline poly_line_arbitrary_hole_data() : p_(0) {}
Chris@16	2139 inline poly_line_arbitrary_hole_data(active_tail_arbitrary* p) : p_(p) {}
Chris@16	2140 //use default copy and assign
Chris@16	2141 inline iterator begin() const { return p_->getTail()->begin(); }
Chris@16	2142 inline iterator end() const { return p_->getTail()->end(); }
Chris@16	2143 //inline compact_iterator_type begin_compact() const { return compact_iterator_type(begin()); }
Chris@16	2144 //inline compact_iterator_type end_compact() const { return compact_iterator_type(end()); }
Chris@16	2145 inline std::size_t size() const { return 0; }
Chris@16	2146 template<class iT>
Chris@16	2147 inline poly_line_arbitrary_hole_data& set(iT inputBegin, iT inputEnd) {
Chris@16	2148 //assert this is not called
Chris@16	2149 return *this;
Chris@16	2150 }
Chris@16	2151 template<class iT>
Chris@16	2152 inline poly_line_arbitrary_hole_data& set_compact(iT inputBegin, iT inputEnd) {
Chris@16	2153 //assert this is not called
Chris@16	2154 return *this;
Chris@16	2155 }
Chris@16	2156 };
Chris@16	2157
Chris@16	2158 template <typename Unit>
Chris@16	2159 class poly_line_arbitrary_polygon_data {
Chris@16	2160 private:
Chris@16	2161 typedef typename polygon_arbitrary_formation<Unit>::active_tail_arbitrary active_tail_arbitrary;
Chris@16	2162 active_tail_arbitrary* p_;
Chris@16	2163 public:
Chris@16	2164 typedef point_data<Unit> Point;
Chris@16	2165 typedef Point point_type;
Chris@16	2166 typedef Unit coordinate_type;
Chris@16	2167 typedef typename active_tail_arbitrary::iterator iterator_type;
Chris@16	2168 //typedef iterator_points_to_compact<iterator_type, Point> compact_iterator_type;
Chris@16	2169 typedef typename coordinate_traits<Unit>::coordinate_distance area_type;
Chris@16	2170
Chris@16	2171 class iterator_holes_type {
Chris@16	2172 private:
Chris@16	2173 typedef poly_line_arbitrary_hole_data<Unit> holeType;
Chris@16	2174 mutable holeType hole_;
Chris@16	2175 typename active_tail_arbitrary::iteratorHoles itr_;
Chris@16	2176
Chris@16	2177 public:
Chris@16	2178 typedef std::forward_iterator_tag iterator_category;
Chris@16	2179 typedef holeType value_type;
Chris@16	2180 typedef std::ptrdiff_t difference_type;
Chris@16	2181 typedef const holeType* pointer; //immutable
Chris@16	2182 typedef const holeType& reference; //immutable
Chris@16	2183 inline iterator_holes_type() : hole_(), itr_() {}
Chris@16	2184 inline iterator_holes_type(typename active_tail_arbitrary::iteratorHoles itr) : hole_(), itr_(itr) {}
Chris@16	2185 inline iterator_holes_type(const iterator_holes_type& that) : hole_(that.hole_), itr_(that.itr_) {}
Chris@16	2186 inline iterator_holes_type& operator=(const iterator_holes_type& that) {
Chris@16	2187 itr_ = that.itr_;
Chris@16	2188 return *this;
Chris@16	2189 }
Chris@16	2190 inline bool operator==(const iterator_holes_type& that) { return itr_ == that.itr_; }
Chris@16	2191 inline bool operator!=(const iterator_holes_type& that) { return itr_ != that.itr_; }
Chris@16	2192 inline iterator_holes_type& operator++() {
Chris@16	2193 ++itr_;
Chris@16	2194 return *this;
Chris@16	2195 }
Chris@16	2196 inline const iterator_holes_type operator++(int) {
Chris@16	2197 iterator_holes_type tmp = *this;
Chris@16	2198 ++(*this);
Chris@16	2199 return tmp;
Chris@16	2200 }
Chris@16	2201 inline reference operator*() {
Chris@16	2202 hole_ = holeType(*itr_);
Chris@16	2203 return hole_;
Chris@16	2204 }
Chris@16	2205 };
Chris@16	2206
Chris@16	2207 typedef poly_line_arbitrary_hole_data<Unit> hole_type;
Chris@16	2208
Chris@16	2209 inline poly_line_arbitrary_polygon_data() : p_(0) {}
Chris@16	2210 inline poly_line_arbitrary_polygon_data(active_tail_arbitrary* p) : p_(p) {}
Chris@16	2211 //use default copy and assign
Chris@16	2212 inline iterator_type begin() const { return p_->getTail()->begin(); }
Chris@16	2213 inline iterator_type end() const { return p_->getTail()->end(); }
Chris@16	2214 //inline compact_iterator_type begin_compact() const { return p_->getTail()->begin(); }
Chris@16	2215 //inline compact_iterator_type end_compact() const { return p_->getTail()->end(); }
Chris@16	2216 inline iterator_holes_type begin_holes() const { return iterator_holes_type(p_->getHoles().begin()); }
Chris@16	2217 inline iterator_holes_type end_holes() const { return iterator_holes_type(p_->getHoles().end()); }
Chris@16	2218 inline active_tail_arbitrary* yield() { return p_; }
Chris@16	2219 //stub out these four required functions that will not be used but are needed for the interface
Chris@16	2220 inline std::size_t size_holes() const { return 0; }
Chris@16	2221 inline std::size_t size() const { return 0; }
Chris@16	2222 template<class iT>
Chris@16	2223 inline poly_line_arbitrary_polygon_data& set(iT inputBegin, iT inputEnd) {
Chris@16	2224 return *this;
Chris@16	2225 }
Chris@16	2226 template<class iT>
Chris@16	2227 inline poly_line_arbitrary_polygon_data& set_compact(iT inputBegin, iT inputEnd) {
Chris@16	2228 return *this;
Chris@16	2229 }
Chris@16	2230 template<class iT>
Chris@16	2231 inline poly_line_arbitrary_polygon_data& set_holes(iT inputBegin, iT inputEnd) {
Chris@16	2232 return *this;
Chris@16	2233 }
Chris@16	2234 };
Chris@16	2235
Chris@16	2236 template <typename Unit>
Chris@16	2237 class trapezoid_arbitrary_formation : public polygon_arbitrary_formation<Unit> {
Chris@16	2238 private:
Chris@16	2239 typedef typename scanline_base<Unit>::Point Point;
Chris@16	2240 typedef typename scanline_base<Unit>::half_edge half_edge;
Chris@16	2241 typedef typename scanline_base<Unit>::vertex_half_edge vertex_half_edge;
Chris@16	2242 typedef typename scanline_base<Unit>::less_vertex_half_edge less_vertex_half_edge;
Chris@16	2243
Chris@16	2244 typedef typename polygon_arbitrary_formation<Unit>::poly_line_arbitrary poly_line_arbitrary;
Chris@16	2245
Chris@16	2246 typedef typename polygon_arbitrary_formation<Unit>::active_tail_arbitrary active_tail_arbitrary;
Chris@16	2247
Chris@16	2248 typedef std::vector<std::pair<Point, int> > vertex_arbitrary_count;
Chris@16	2249
Chris@16	2250 typedef typename polygon_arbitrary_formation<Unit>::less_half_edge_count less_half_edge_count;
Chris@16	2251
Chris@16	2252 typedef std::vector<std::pair<std::pair<std::pair<Point, Point>, int>, active_tail_arbitrary*> > incoming_count;
Chris@16	2253
Chris@16	2254 typedef typename polygon_arbitrary_formation<Unit>::less_incoming_count less_incoming_count;
Chris@16	2255
Chris@16	2256 typedef typename polygon_arbitrary_formation<Unit>::vertex_arbitrary_compact vertex_arbitrary_compact;
Chris@16	2257
Chris@16	2258 private:
Chris@16	2259 //definitions
Chris@16	2260 typedef std::map<vertex_half_edge, active_tail_arbitrary*, less_vertex_half_edge> scanline_data;
Chris@16	2261 typedef typename scanline_data::iterator iterator;
Chris@16	2262 typedef typename scanline_data::const_iterator const_iterator;
Chris@16	2263
Chris@16	2264 //data
Chris@16	2265 public:
Chris@16	2266 inline trapezoid_arbitrary_formation() : polygon_arbitrary_formation<Unit>() {}
Chris@16	2267 inline trapezoid_arbitrary_formation(const trapezoid_arbitrary_formation& that) : polygon_arbitrary_formation<Unit>(that) {}
Chris@16	2268 inline trapezoid_arbitrary_formation& operator=(const trapezoid_arbitrary_formation& that) {
Chris@16	2269 * static_cast<polygon_arbitrary_formation<Unit>>(this) = static_cast<polygon_arbitrary_formation<Unit>*>(&that);
Chris@16	2270 return *this;
Chris@16	2271 }
Chris@16	2272
Chris@16	2273 //cT is an output container of Polygon45 or Polygon45WithHoles
Chris@16	2274 //iT is an iterator over vertex_half_edge elements
Chris@16	2275 //inputBegin - inputEnd is a range of sorted iT that represents
Chris@16	2276 //one or more scanline stops worth of data
Chris@16	2277 template <class cT, class iT>
Chris@16	2278 void scan(cT& output, iT inputBegin, iT inputEnd) {
Chris@16	2279 //std::cout << "1\n";
Chris@16	2280 while(inputBegin != inputEnd) {
Chris@16	2281 //std::cout << "2\n";
Chris@16	2282 polygon_arbitrary_formation<Unit>::x_ = (*inputBegin).pt.get(HORIZONTAL);
Chris@16	2283 //std::cout << "SCAN FORMATION " << x_ << "\n";
Chris@16	2284 //std::cout << "x_ = " << x_ << "\n";
Chris@16	2285 //std::cout << "scan line size: " << scanData_.size() << "\n";
Chris@16	2286 inputBegin = processEvent_(output, inputBegin, inputEnd);
Chris@16	2287 }
Chris@16	2288 //std::cout << "scan line size: " << scanData_.size() << "\n";
Chris@16	2289 }
Chris@16	2290
Chris@16	2291 private:
Chris@16	2292 //functions
Chris@16	2293 inline void getVerticalPair_(std::pair<active_tail_arbitrary*,
Chris@16	2294 active_tail_arbitrary*>& verticalPair,
Chris@16	2295 iterator previter) {
Chris@16	2296 active_tail_arbitrary* iterTail = (*previter).second;
Chris@16	2297 Point prevPoint(polygon_arbitrary_formation<Unit>::x_,
Chris@16	2298 convert_high_precision_type<Unit>(previter->first.evalAtX(polygon_arbitrary_formation<Unit>::x_)));
Chris@16	2299 iterTail->pushPoint(prevPoint);
Chris@16	2300 std::pair<active_tail_arbitrary, active_tail_arbitrary> tailPair =
Chris@16	2301 active_tail_arbitrary::createActiveTailsAsPair(prevPoint, true, 0, false);
Chris@16	2302 verticalPair.first = iterTail;
Chris@16	2303 verticalPair.second = tailPair.first;
Chris@16	2304 (*previter).second = tailPair.second;
Chris@16	2305 }
Chris@16	2306
Chris@16	2307 template <class cT, class cT2>
Chris@16	2308 inline std::pair<std::pair<Point, int>, active_tail_arbitrary*>
Chris@16	2309 processPoint_(cT& output, cT2& elements,
Chris@16	2310 std::pair<active_tail_arbitrary, active_tail_arbitrary>& verticalPair,
Chris@16	2311 iterator previter, Point point, incoming_count& counts_from_scanline,
Chris@16	2312 vertex_arbitrary_count& incoming_count) {
Chris@16	2313 //std::cout << "\nAT POINT: " << point << "\n";
Chris@16	2314 //join any closing solid corners
Chris@16	2315 std::vector<int> counts;
Chris@16	2316 std::vector<int> incoming;
Chris@16	2317 std::vector<active_tail_arbitrary*> tails;
Chris@16	2318 counts.reserve(counts_from_scanline.size());
Chris@16	2319 tails.reserve(counts_from_scanline.size());
Chris@16	2320 incoming.reserve(incoming_count.size());
Chris@16	2321 for(std::size_t i = 0; i < counts_from_scanline.size(); ++i) {
Chris@16	2322 counts.push_back(counts_from_scanline[i].first.second);
Chris@16	2323 tails.push_back(counts_from_scanline[i].second);
Chris@16	2324 }
Chris@16	2325 for(std::size_t i = 0; i < incoming_count.size(); ++i) {
Chris@16	2326 incoming.push_back(incoming_count[i].second);
Chris@16	2327 if(incoming_count[i].first < point) {
Chris@16	2328 incoming.back() = 0;
Chris@16	2329 }
Chris@16	2330 }
Chris@16	2331
Chris@16	2332 active_tail_arbitrary* returnValue = 0;
Chris@16	2333 std::pair<active_tail_arbitrary, active_tail_arbitrary> verticalPairOut;
Chris@16	2334 verticalPairOut.first = 0;
Chris@16	2335 verticalPairOut.second = 0;
Chris@16	2336 std::pair<Point, int> returnCount(Point(0, 0), 0);
Chris@16	2337 int i_size_less_1 = (int)(incoming.size()) -1;
Chris@16	2338 int c_size_less_1 = (int)(counts.size()) -1;
Chris@16	2339 int i_size = incoming.size();
Chris@16	2340 int c_size = counts.size();
Chris@16	2341
Chris@16	2342 bool have_vertical_tail_from_below = false;
Chris@16	2343 if(c_size &&
Chris@16	2344 scanline_base<Unit>::is_vertical(counts_from_scanline.back().first.first)) {
Chris@16	2345 have_vertical_tail_from_below = true;
Chris@16	2346 }
Chris@16	2347 //assert size = size_less_1 + 1
Chris@16	2348 //std::cout << tails.size() << " " << incoming.size() << " " << counts_from_scanline.size() << " " << incoming_count.size() << "\n";
Chris@16	2349 // for(std::size_t i = 0; i < counts.size(); ++i) {
Chris@16	2350 // std::cout << counts_from_scanline[i].first.first.first.get(HORIZONTAL) << ",";
Chris@16	2351 // std::cout << counts_from_scanline[i].first.first.first.get(VERTICAL) << " ";
Chris@16	2352 // std::cout << counts_from_scanline[i].first.first.second.get(HORIZONTAL) << ",";
Chris@16	2353 // std::cout << counts_from_scanline[i].first.first.second.get(VERTICAL) << ":";
Chris@16	2354 // std::cout << counts_from_scanline[i].first.second << " ";
Chris@16	2355 // } std::cout << "\n";
Chris@16	2356 // print(incoming_count);
Chris@16	2357 {
Chris@16	2358 for(int i = 0; i < c_size_less_1; ++i) {
Chris@16	2359 //std::cout << i << "\n";
Chris@16	2360 if(counts[i] == -1) {
Chris@16	2361 //std::cout << "fixed i\n";
Chris@16	2362 for(int j = i + 1; j < c_size; ++j) {
Chris@16	2363 //std::cout << j << "\n";
Chris@16	2364 if(counts[j]) {
Chris@16	2365 if(counts[j] == 1) {
Chris@16	2366 //std::cout << "case1: " << i << " " << j << "\n";
Chris@16	2367 //if a figure is closed it will be written out by this function to output
Chris@16	2368 active_tail_arbitrary::joinChains(point, tails[i], tails[j], true, output);
Chris@16	2369 counts[i] = 0;
Chris@16	2370 counts[j] = 0;
Chris@16	2371 tails[i] = 0;
Chris@16	2372 tails[j] = 0;
Chris@16	2373 }
Chris@16	2374 break;
Chris@16	2375 }
Chris@16	2376 }
Chris@16	2377 }
Chris@16	2378 }
Chris@16	2379 }
Chris@16	2380 //find any pairs of incoming edges that need to create pair for leading solid
Chris@16	2381 //std::cout << "checking case2\n";
Chris@16	2382 {
Chris@16	2383 for(int i = 0; i < i_size_less_1; ++i) {
Chris@16	2384 //std::cout << i << "\n";
Chris@16	2385 if(incoming[i] == 1) {
Chris@16	2386 //std::cout << "fixed i\n";
Chris@16	2387 for(int j = i + 1; j < i_size; ++j) {
Chris@16	2388 //std::cout << j << "\n";
Chris@16	2389 if(incoming[j]) {
Chris@16	2390 //std::cout << incoming[j] << "\n";
Chris@16	2391 if(incoming[j] == -1) {
Chris@16	2392 //std::cout << "case2: " << i << " " << j << "\n";
Chris@16	2393 //std::cout << "creating active tail pair\n";
Chris@16	2394 std::pair<active_tail_arbitrary, active_tail_arbitrary> tailPair =
Chris@16	2395 active_tail_arbitrary::createActiveTailsAsPair(point, true, 0, polygon_arbitrary_formation<Unit>::fractureHoles_ != 0);
Chris@16	2396 //tailPair.first->print();
Chris@16	2397 //tailPair.second->print();
Chris@16	2398 if(j == i_size_less_1 && incoming_count[j].first.get(HORIZONTAL) == point.get(HORIZONTAL)) {
Chris@16	2399 //vertical active tail becomes return value
Chris@16	2400 returnValue = tailPair.first;
Chris@16	2401 returnCount.first = point;
Chris@16	2402 returnCount.second = 1;
Chris@16	2403 } else {
Chris@16	2404 //std::cout << "new element " << j-1 << " " << -1 << "\n";
Chris@16	2405 //std::cout << point << " " << incoming_count[j].first << "\n";
Chris@16	2406 elements.push_back(std::pair<vertex_half_edge,
Chris@16	2407 active_tail_arbitrary*>(vertex_half_edge(point,
Chris@16	2408 incoming_count[j].first, -1), tailPair.first));
Chris@16	2409 }
Chris@16	2410 //std::cout << "new element " << i-1 << " " << 1 << "\n";
Chris@16	2411 //std::cout << point << " " << incoming_count[i].first << "\n";
Chris@16	2412 elements.push_back(std::pair<vertex_half_edge,
Chris@16	2413 active_tail_arbitrary*>(vertex_half_edge(point,
Chris@16	2414 incoming_count[i].first, 1), tailPair.second));
Chris@16	2415 incoming[i] = 0;
Chris@16	2416 incoming[j] = 0;
Chris@16	2417 }
Chris@16	2418 break;
Chris@16	2419 }
Chris@16	2420 }
Chris@16	2421 }
Chris@16	2422 }
Chris@16	2423 }
Chris@16	2424 //find any active tail that needs to pass through to an incoming edge
Chris@16	2425 //we expect to find no more than two pass through
Chris@16	2426
Chris@16	2427 //find pass through with solid on top
Chris@16	2428 {
Chris@16	2429 //std::cout << "checking case 3\n";
Chris@16	2430 for(int i = 0; i < c_size; ++i) {
Chris@16	2431 //std::cout << i << "\n";
Chris@16	2432 if(counts[i] != 0) {
Chris@16	2433 if(counts[i] == 1) {
Chris@16	2434 //std::cout << "fixed i\n";
Chris@16	2435 for(int j = i_size_less_1; j >= 0; --j) {
Chris@16	2436 if(incoming[j] != 0) {
Chris@16	2437 if(incoming[j] == 1) {
Chris@16	2438 //std::cout << "case3: " << i << " " << j << "\n";
Chris@16	2439 //tails[i]->print();
Chris@16	2440 //pass through solid on top
Chris@16	2441 tails[i]->pushPoint(point);
Chris@16	2442 //std::cout << "after push\n";
Chris@16	2443 if(j == i_size_less_1 && incoming_count[j].first.get(HORIZONTAL) == point.get(HORIZONTAL)) {
Chris@16	2444 returnValue = tails[i];
Chris@16	2445 returnCount.first = point;
Chris@16	2446 returnCount.second = -1;
Chris@16	2447 } else {
Chris@16	2448 std::pair<active_tail_arbitrary, active_tail_arbitrary> tailPair =
Chris@16	2449 active_tail_arbitrary::createActiveTailsAsPair(point, true, 0, false);
Chris@16	2450 verticalPairOut.first = tails[i];
Chris@16	2451 verticalPairOut.second = tailPair.first;
Chris@16	2452 elements.push_back(std::pair<vertex_half_edge,
Chris@16	2453 active_tail_arbitrary*>(vertex_half_edge(point,
Chris@16	2454 incoming_count[j].first, incoming[j]), tailPair.second));
Chris@16	2455 }
Chris@16	2456 tails[i] = 0;
Chris@16	2457 counts[i] = 0;
Chris@16	2458 incoming[j] = 0;
Chris@16	2459 }
Chris@16	2460 break;
Chris@16	2461 }
Chris@16	2462 }
Chris@16	2463 }
Chris@16	2464 break;
Chris@16	2465 }
Chris@16	2466 }
Chris@16	2467 }
Chris@16	2468 //std::cout << "checking case 4\n";
Chris@16	2469 //find pass through with solid on bottom
Chris@16	2470 {
Chris@16	2471 for(int i = c_size_less_1; i >= 0; --i) {
Chris@16	2472 //std::cout << "i = " << i << " with count " << counts[i] << "\n";
Chris@16	2473 if(counts[i] != 0) {
Chris@16	2474 if(counts[i] == -1) {
Chris@16	2475 for(int j = 0; j < i_size; ++j) {
Chris@16	2476 if(incoming[j] != 0) {
Chris@16	2477 if(incoming[j] == -1) {
Chris@16	2478 //std::cout << "case4: " << i << " " << j << "\n";
Chris@16	2479 //pass through solid on bottom
Chris@16	2480
Chris@16	2481 //if count from scanline is vertical
Chris@16	2482 if(i == c_size_less_1 &&
Chris@16	2483 counts_from_scanline[i].first.first.first.get(HORIZONTAL) ==
Chris@16	2484 point.get(HORIZONTAL)) {
Chris@16	2485 //if incoming count is vertical
Chris@16	2486 if(j == i_size_less_1 &&
Chris@16	2487 incoming_count[j].first.get(HORIZONTAL) == point.get(HORIZONTAL)) {
Chris@16	2488 returnValue = tails[i];
Chris@16	2489 returnCount.first = point;
Chris@16	2490 returnCount.second = 1;
Chris@16	2491 } else {
Chris@16	2492 tails[i]->pushPoint(point);
Chris@16	2493 elements.push_back(std::pair<vertex_half_edge,
Chris@16	2494 active_tail_arbitrary*>(vertex_half_edge(point,
Chris@16	2495 incoming_count[j].first, incoming[j]), tails[i]));
Chris@16	2496 }
Chris@16	2497 } else if(j == i_size_less_1 &&
Chris@16	2498 incoming_count[j].first.get(HORIZONTAL) ==
Chris@16	2499 point.get(HORIZONTAL)) {
Chris@16	2500 if(verticalPair.first == 0) {
Chris@16	2501 getVerticalPair_(verticalPair, previter);
Chris@16	2502 }
Chris@16	2503 active_tail_arbitrary::joinChains(point, tails[i], verticalPair.first, true, output);
Chris@16	2504 returnValue = verticalPair.second;
Chris@16	2505 returnCount.first = point;
Chris@16	2506 returnCount.second = 1;
Chris@16	2507 } else {
Chris@16	2508 //neither is vertical
Chris@16	2509 if(verticalPair.first == 0) {
Chris@16	2510 getVerticalPair_(verticalPair, previter);
Chris@16	2511 }
Chris@16	2512 active_tail_arbitrary::joinChains(point, tails[i], verticalPair.first, true, output);
Chris@16	2513 verticalPair.second->pushPoint(point);
Chris@16	2514 elements.push_back(std::pair<vertex_half_edge,
Chris@16	2515 active_tail_arbitrary*>(vertex_half_edge(point,
Chris@16	2516 incoming_count[j].first, incoming[j]), verticalPair.second));
Chris@16	2517 }
Chris@16	2518 tails[i] = 0;
Chris@16	2519 counts[i] = 0;
Chris@16	2520 incoming[j] = 0;
Chris@16	2521 }
Chris@16	2522 break;
Chris@16	2523 }
Chris@16	2524 }
Chris@16	2525 }
Chris@16	2526 break;
Chris@16	2527 }
Chris@16	2528 }
Chris@16	2529 }
Chris@16	2530 //find the end of a hole or the beginning of a hole
Chris@16	2531
Chris@16	2532 //find end of a hole
Chris@16	2533 {
Chris@16	2534 for(int i = 0; i < c_size_less_1; ++i) {
Chris@16	2535 if(counts[i] != 0) {
Chris@16	2536 for(int j = i+1; j < c_size; ++j) {
Chris@16	2537 if(counts[j] != 0) {
Chris@16	2538 //std::cout << "case5: " << i << " " << j << "\n";
Chris@16	2539 //we are ending a hole and may potentially close a figure and have to handle the hole
Chris@16	2540 tails[i]->pushPoint(point);
Chris@16	2541 verticalPairOut.first = tails[i];
Chris@16	2542 if(j == c_size_less_1 &&
Chris@16	2543 counts_from_scanline[j].first.first.first.get(HORIZONTAL) ==
Chris@16	2544 point.get(HORIZONTAL)) {
Chris@16	2545 verticalPairOut.second = tails[j];
Chris@16	2546 } else {
Chris@16	2547 //need to close a trapezoid below
Chris@16	2548 if(verticalPair.first == 0) {
Chris@16	2549 getVerticalPair_(verticalPair, previter);
Chris@16	2550 }
Chris@16	2551 active_tail_arbitrary::joinChains(point, tails[j], verticalPair.first, true, output);
Chris@16	2552 verticalPairOut.second = verticalPair.second;
Chris@16	2553 }
Chris@16	2554 tails[i] = 0;
Chris@16	2555 tails[j] = 0;
Chris@16	2556 counts[i] = 0;
Chris@16	2557 counts[j] = 0;
Chris@16	2558 break;
Chris@16	2559 }
Chris@16	2560 }
Chris@16	2561 break;
Chris@16	2562 }
Chris@16	2563 }
Chris@16	2564 }
Chris@16	2565 //find beginning of a hole
Chris@16	2566 {
Chris@16	2567 for(int i = 0; i < i_size_less_1; ++i) {
Chris@16	2568 if(incoming[i] != 0) {
Chris@16	2569 for(int j = i+1; j < i_size; ++j) {
Chris@16	2570 if(incoming[j] != 0) {
Chris@16	2571 //std::cout << "case6: " << i << " " << j << "\n";
Chris@16	2572 //we are beginning a empty space
Chris@16	2573 if(verticalPair.first == 0) {
Chris@16	2574 getVerticalPair_(verticalPair, previter);
Chris@16	2575 }
Chris@16	2576 verticalPair.second->pushPoint(point);
Chris@16	2577 if(j == i_size_less_1 &&
Chris@16	2578 incoming_count[j].first.get(HORIZONTAL) == point.get(HORIZONTAL)) {
Chris@16	2579 returnValue = verticalPair.first;
Chris@16	2580 returnCount.first = point;
Chris@16	2581 returnCount.second = -1;
Chris@16	2582 } else {
Chris@16	2583 std::pair<active_tail_arbitrary, active_tail_arbitrary> tailPair =
Chris@16	2584 active_tail_arbitrary::createActiveTailsAsPair(point, false, 0, false);
Chris@16	2585 elements.push_back(std::pair<vertex_half_edge,
Chris@16	2586 active_tail_arbitrary*>(vertex_half_edge(point,
Chris@16	2587 incoming_count[j].first, incoming[j]), tailPair.second));
Chris@16	2588 verticalPairOut.second = tailPair.first;
Chris@16	2589 verticalPairOut.first = verticalPair.first;
Chris@16	2590 }
Chris@16	2591 elements.push_back(std::pair<vertex_half_edge,
Chris@16	2592 active_tail_arbitrary*>(vertex_half_edge(point,
Chris@16	2593 incoming_count[i].first, incoming[i]), verticalPair.second));
Chris@16	2594 incoming[i] = 0;
Chris@16	2595 incoming[j] = 0;
Chris@16	2596 break;
Chris@16	2597 }
Chris@16	2598 }
Chris@16	2599 break;
Chris@16	2600 }
Chris@16	2601 }
Chris@16	2602 }
Chris@16	2603 if(have_vertical_tail_from_below) {
Chris@16	2604 if(tails.back()) {
Chris@16	2605 tails.back()->pushPoint(point);
Chris@16	2606 returnValue = tails.back();
Chris@16	2607 returnCount.first = point;
Chris@16	2608 returnCount.second = counts.back();
Chris@16	2609 }
Chris@16	2610 }
Chris@16	2611 verticalPair = verticalPairOut;
Chris@16	2612 //assert that tails, counts and incoming are all null
Chris@16	2613 return std::pair<std::pair<Point, int>, active_tail_arbitrary*>(returnCount, returnValue);
Chris@16	2614 }
Chris@16	2615
Chris@16	2616 static inline void print(const vertex_arbitrary_count& count) {
Chris@16	2617 for(unsigned i = 0; i < count.size(); ++i) {
Chris@16	2618 //std::cout << count[i].first.get(HORIZONTAL) << ",";
Chris@16	2619 //std::cout << count[i].first.get(VERTICAL) << ":";
Chris@16	2620 //std::cout << count[i].second << " ";
Chris@16	2621 } //std::cout << "\n";
Chris@16	2622 }
Chris@16	2623
Chris@16	2624 static inline void print(const scanline_data& data) {
Chris@16	2625 for(typename scanline_data::const_iterator itr = data.begin(); itr != data.end(); ++itr){
Chris@16	2626 //std::cout << itr->first.pt << ", " << itr->first.other_pt << "; ";
Chris@16	2627 } //std::cout << "\n";
Chris@16	2628 }
Chris@16	2629
Chris@16	2630 template <class cT, class iT>
Chris@16	2631 inline iT processEvent_(cT& output, iT inputBegin, iT inputEnd) {
Chris@101	2632 //typedef typename high_precision_type<Unit>::type high_precision;
Chris@16	2633 //std::cout << "processEvent_\n";
Chris@16	2634 polygon_arbitrary_formation<Unit>::justBefore_ = true;
Chris@16	2635 //collect up all elements from the tree that are at the y
Chris@16	2636 //values of events in the input queue
Chris@16	2637 //create vector of new elements to add into tree
Chris@16	2638 active_tail_arbitrary* verticalTail = 0;
Chris@16	2639 std::pair<active_tail_arbitrary, active_tail_arbitrary> verticalPair;
Chris@16	2640 std::pair<Point, int> verticalCount(Point(0, 0), 0);
Chris@16	2641 iT currentIter = inputBegin;
Chris@16	2642 std::vector<iterator> elementIters;
Chris@16	2643 std::vector<std::pair<vertex_half_edge, active_tail_arbitrary*> > elements;
Chris@16	2644 while(currentIter != inputEnd && currentIter->pt.get(HORIZONTAL) == polygon_arbitrary_formation<Unit>::x_) {
Chris@16	2645 //std::cout << "loop\n";
Chris@16	2646 Unit currentY = (*currentIter).pt.get(VERTICAL);
Chris@16	2647 //std::cout << "current Y " << currentY << "\n";
Chris@16	2648 //std::cout << "scanline size " << scanData_.size() << "\n";
Chris@16	2649 //print(scanData_);
Chris@16	2650 iterator iter = this->lookUp_(currentY);
Chris@16	2651 //std::cout << "found element in scanline " << (iter != scanData_.end()) << "\n";
Chris@16	2652 //int counts[4] = {0, 0, 0, 0};
Chris@16	2653 incoming_count counts_from_scanline;
Chris@16	2654 //std::cout << "finding elements in tree\n";
Chris@16	2655 //if(iter != scanData_.end())
Chris@16	2656 // std::cout << "first iter y is " << iter->first.evalAtX(x_) << "\n";
Chris@16	2657 iterator previter = iter;
Chris@16	2658 if(previter != polygon_arbitrary_formation<Unit>::scanData_.end() &&
Chris@16	2659 previter->first.evalAtX(polygon_arbitrary_formation<Unit>::x_) >= currentY &&
Chris@16	2660 previter != polygon_arbitrary_formation<Unit>::scanData_.begin())
Chris@16	2661 --previter;
Chris@16	2662 while(iter != polygon_arbitrary_formation<Unit>::scanData_.end() &&
Chris@16	2663 ((iter->first.pt.x() == polygon_arbitrary_formation<Unit>::x_ && iter->first.pt.y() == currentY) \|\|
Chris@16	2664 (iter->first.other_pt.x() == polygon_arbitrary_formation<Unit>::x_ && iter->first.other_pt.y() == currentY))) {
Chris@16	2665 //iter->first.evalAtX(polygon_arbitrary_formation<Unit>::x_) == (high_precision)currentY) {
Chris@16	2666 //std::cout << "loop2\n";
Chris@16	2667 elementIters.push_back(iter);
Chris@16	2668 counts_from_scanline.push_back(std::pair<std::pair<std::pair<Point, Point>, int>, active_tail_arbitrary*>
Chris@16	2669 (std::pair<std::pair<Point, Point>, int>(std::pair<Point, Point>(iter->first.pt,
Chris@16	2670 iter->first.other_pt),
Chris@16	2671 iter->first.count),
Chris@16	2672 iter->second));
Chris@16	2673 ++iter;
Chris@16	2674 }
Chris@16	2675 Point currentPoint(polygon_arbitrary_formation<Unit>::x_, currentY);
Chris@16	2676 //std::cout << "counts_from_scanline size " << counts_from_scanline.size() << "\n";
Chris@16	2677 this->sort_incoming_count(counts_from_scanline, currentPoint);
Chris@16	2678
Chris@16	2679 vertex_arbitrary_count incoming;
Chris@16	2680 //std::cout << "aggregating\n";
Chris@16	2681 do {
Chris@16	2682 //std::cout << "loop3\n";
Chris@16	2683 const vertex_half_edge& elem = *currentIter;
Chris@16	2684 incoming.push_back(std::pair<Point, int>(elem.other_pt, elem.count));
Chris@16	2685 ++currentIter;
Chris@16	2686 } while(currentIter != inputEnd && currentIter->pt.get(VERTICAL) == currentY &&
Chris@16	2687 currentIter->pt.get(HORIZONTAL) == polygon_arbitrary_formation<Unit>::x_);
Chris@16	2688 //print(incoming);
Chris@16	2689 this->sort_vertex_arbitrary_count(incoming, currentPoint);
Chris@16	2690 //std::cout << currentPoint.get(HORIZONTAL) << "," << currentPoint.get(VERTICAL) << "\n";
Chris@16	2691 //print(incoming);
Chris@16	2692 //std::cout << "incoming counts from input size " << incoming.size() << "\n";
Chris@16	2693 //compact_vertex_arbitrary_count(currentPoint, incoming);
Chris@16	2694 vertex_arbitrary_count tmp;
Chris@16	2695 tmp.reserve(incoming.size());
Chris@16	2696 for(std::size_t i = 0; i < incoming.size(); ++i) {
Chris@16	2697 if(currentPoint < incoming[i].first) {
Chris@16	2698 tmp.push_back(incoming[i]);
Chris@16	2699 }
Chris@16	2700 }
Chris@16	2701 incoming.swap(tmp);
Chris@16	2702 //std::cout << "incoming counts from input size " << incoming.size() << "\n";
Chris@16	2703 //now counts_from_scanline has the data from the left and
Chris@16	2704 //incoming has the data from the right at this point
Chris@16	2705 //cancel out any end points
Chris@16	2706 if(verticalTail) {
Chris@16	2707 //std::cout << "adding vertical tail to counts from scanline\n";
Chris@16	2708 //std::cout << -verticalCount.second << "\n";
Chris@16	2709 counts_from_scanline.push_back(std::pair<std::pair<std::pair<Point, Point>, int>, active_tail_arbitrary*>
Chris@16	2710 (std::pair<std::pair<Point, Point>, int>(std::pair<Point, Point>(verticalCount.first,
Chris@16	2711 currentPoint),
Chris@16	2712 -verticalCount.second),
Chris@16	2713 verticalTail));
Chris@16	2714 }
Chris@16	2715 if(!incoming.empty() && incoming.back().first.get(HORIZONTAL) == polygon_arbitrary_formation<Unit>::x_) {
Chris@16	2716 //std::cout << "inverted vertical event\n";
Chris@16	2717 incoming.back().second *= -1;
Chris@16	2718 }
Chris@16	2719 //std::cout << "calling processPoint_\n";
Chris@16	2720 std::pair<std::pair<Point, int>, active_tail_arbitrary*> result = processPoint_(output, elements, verticalPair, previter, Point(polygon_arbitrary_formation<Unit>::x_, currentY), counts_from_scanline, incoming);
Chris@16	2721 verticalCount = result.first;
Chris@16	2722 verticalTail = result.second;
Chris@16	2723 if(verticalPair.first != 0 && iter != polygon_arbitrary_formation<Unit>::scanData_.end() &&
Chris@16	2724 (currentIter == inputEnd \|\| currentIter->pt.x() != polygon_arbitrary_formation<Unit>::x_ \|\|
Chris@16	2725 currentIter->pt.y() > (*iter).first.evalAtX(polygon_arbitrary_formation<Unit>::x_))) {
Chris@16	2726 //splice vertical pair into edge above
Chris@16	2727 active_tail_arbitrary* tailabove = (*iter).second;
Chris@16	2728 Point point(polygon_arbitrary_formation<Unit>::x_,
Chris@16	2729 convert_high_precision_type<Unit>((*iter).first.evalAtX(polygon_arbitrary_formation<Unit>::x_)));
Chris@16	2730 verticalPair.second->pushPoint(point);
Chris@16	2731 active_tail_arbitrary::joinChains(point, tailabove, verticalPair.first, true, output);
Chris@16	2732 (*iter).second = verticalPair.second;
Chris@16	2733 verticalPair.first = 0;
Chris@16	2734 verticalPair.second = 0;
Chris@16	2735 }
Chris@16	2736 }
Chris@16	2737 //std::cout << "erasing\n";
Chris@16	2738 //erase all elements from the tree
Chris@16	2739 for(typename std::vector<iterator>::iterator iter = elementIters.begin();
Chris@16	2740 iter != elementIters.end(); ++iter) {
Chris@16	2741 //std::cout << "erasing loop\n";
Chris@16	2742 polygon_arbitrary_formation<Unit>::scanData_.erase(*iter);
Chris@16	2743 }
Chris@16	2744 //switch comparison tie breaking policy
Chris@16	2745 polygon_arbitrary_formation<Unit>::justBefore_ = false;
Chris@16	2746 //add new elements into tree
Chris@16	2747 //std::cout << "inserting\n";
Chris@16	2748 for(typename std::vector<std::pair<vertex_half_edge, active_tail_arbitrary*> >::iterator iter = elements.begin();
Chris@16	2749 iter != elements.end(); ++iter) {
Chris@16	2750 //std::cout << "inserting loop\n";
Chris@16	2751 polygon_arbitrary_formation<Unit>::scanData_.insert(polygon_arbitrary_formation<Unit>::scanData_.end(), *iter);
Chris@16	2752 }
Chris@16	2753 //std::cout << "end processEvent\n";
Chris@16	2754 return currentIter;
Chris@16	2755 }
Chris@16	2756 public:
Chris@16	2757 template <typename stream_type>
Chris@16	2758 static inline bool testTrapezoidArbitraryFormationRect(stream_type& stdcout) {
Chris@16	2759 stdcout << "testing trapezoid formation\n";
Chris@16	2760 trapezoid_arbitrary_formation pf;
Chris@16	2761 std::vector<polygon_data<Unit> > polys;
Chris@16	2762 std::vector<vertex_half_edge> data;
Chris@16	2763 data.push_back(vertex_half_edge(Point(0, 0), Point(10, 0), 1));
Chris@16	2764 data.push_back(vertex_half_edge(Point(0, 0), Point(0, 10), 1));
Chris@16	2765 data.push_back(vertex_half_edge(Point(0, 10), Point(0, 0), -1));
Chris@16	2766 data.push_back(vertex_half_edge(Point(0, 10), Point(10, 10), -1));
Chris@16	2767 data.push_back(vertex_half_edge(Point(10, 0), Point(0, 0), -1));
Chris@16	2768 data.push_back(vertex_half_edge(Point(10, 0), Point(10, 10), -1));
Chris@16	2769 data.push_back(vertex_half_edge(Point(10, 10), Point(10, 0), 1));
Chris@16	2770 data.push_back(vertex_half_edge(Point(10, 10), Point(0, 10), 1));
Chris@16	2771 polygon_sort(data.begin(), data.end());
Chris@16	2772 pf.scan(polys, data.begin(), data.end());
Chris@16	2773 stdcout << "result size: " << polys.size() << "\n";
Chris@16	2774 for(std::size_t i = 0; i < polys.size(); ++i) {
Chris@16	2775 stdcout << polys[i] << "\n";
Chris@16	2776 }
Chris@16	2777 stdcout << "done testing trapezoid formation\n";
Chris@16	2778 return true;
Chris@16	2779 }
Chris@16	2780 template <typename stream_type>
Chris@16	2781 static inline bool testTrapezoidArbitraryFormationP1(stream_type& stdcout) {
Chris@16	2782 stdcout << "testing trapezoid formation P1\n";
Chris@16	2783 trapezoid_arbitrary_formation pf;
Chris@16	2784 std::vector<polygon_data<Unit> > polys;
Chris@16	2785 std::vector<vertex_half_edge> data;
Chris@16	2786 data.push_back(vertex_half_edge(Point(0, 0), Point(10, 10), 1));
Chris@16	2787 data.push_back(vertex_half_edge(Point(0, 0), Point(0, 10), 1));
Chris@16	2788 data.push_back(vertex_half_edge(Point(0, 10), Point(0, 0), -1));
Chris@16	2789 data.push_back(vertex_half_edge(Point(0, 10), Point(10, 20), -1));
Chris@16	2790 data.push_back(vertex_half_edge(Point(10, 10), Point(0, 0), -1));
Chris@16	2791 data.push_back(vertex_half_edge(Point(10, 10), Point(10, 20), -1));
Chris@16	2792 data.push_back(vertex_half_edge(Point(10, 20), Point(10, 10), 1));
Chris@16	2793 data.push_back(vertex_half_edge(Point(10, 20), Point(0, 10), 1));
Chris@16	2794 polygon_sort(data.begin(), data.end());
Chris@16	2795 pf.scan(polys, data.begin(), data.end());
Chris@16	2796 stdcout << "result size: " << polys.size() << "\n";
Chris@16	2797 for(std::size_t i = 0; i < polys.size(); ++i) {
Chris@16	2798 stdcout << polys[i] << "\n";
Chris@16	2799 }
Chris@16	2800 stdcout << "done testing trapezoid formation\n";
Chris@16	2801 return true;
Chris@16	2802 }
Chris@16	2803 template <typename stream_type>
Chris@16	2804 static inline bool testTrapezoidArbitraryFormationP2(stream_type& stdcout) {
Chris@16	2805 stdcout << "testing trapezoid formation P2\n";
Chris@16	2806 trapezoid_arbitrary_formation pf;
Chris@16	2807 std::vector<polygon_data<Unit> > polys;
Chris@16	2808 std::vector<vertex_half_edge> data;
Chris@16	2809 data.push_back(vertex_half_edge(Point(-3, 1), Point(2, -4), 1));
Chris@16	2810 data.push_back(vertex_half_edge(Point(-3, 1), Point(-2, 2), -1));
Chris@16	2811 data.push_back(vertex_half_edge(Point(-2, 2), Point(2, 4), -1));
Chris@16	2812 data.push_back(vertex_half_edge(Point(-2, 2), Point(-3, 1), 1));
Chris@16	2813 data.push_back(vertex_half_edge(Point(2, -4), Point(-3, 1), -1));
Chris@16	2814 data.push_back(vertex_half_edge(Point(2, -4), Point(2, 4), -1));
Chris@16	2815 data.push_back(vertex_half_edge(Point(2, 4), Point(-2, 2), 1));
Chris@16	2816 data.push_back(vertex_half_edge(Point(2, 4), Point(2, -4), 1));
Chris@16	2817 polygon_sort(data.begin(), data.end());
Chris@16	2818 pf.scan(polys, data.begin(), data.end());
Chris@16	2819 stdcout << "result size: " << polys.size() << "\n";
Chris@16	2820 for(std::size_t i = 0; i < polys.size(); ++i) {
Chris@16	2821 stdcout << polys[i] << "\n";
Chris@16	2822 }
Chris@16	2823 stdcout << "done testing trapezoid formation\n";
Chris@16	2824 return true;
Chris@16	2825 }
Chris@16	2826
Chris@16	2827 template <typename stream_type>
Chris@16	2828 static inline bool testTrapezoidArbitraryFormationPolys(stream_type& stdcout) {
Chris@16	2829 stdcout << "testing trapezoid formation polys\n";
Chris@16	2830 trapezoid_arbitrary_formation pf;
Chris@16	2831 std::vector<polygon_with_holes_data<Unit> > polys;
Chris@16	2832 //trapezoid_arbitrary_formation pf2(true);
Chris@16	2833 //std::vector<polygon_with_holes_data<Unit> > polys2;
Chris@16	2834 std::vector<vertex_half_edge> data;
Chris@16	2835 data.push_back(vertex_half_edge(Point(0, 0), Point(100, 1), 1));
Chris@16	2836 data.push_back(vertex_half_edge(Point(0, 0), Point(1, 100), -1));
Chris@16	2837 data.push_back(vertex_half_edge(Point(1, 100), Point(0, 0), 1));
Chris@16	2838 data.push_back(vertex_half_edge(Point(1, 100), Point(101, 101), -1));
Chris@16	2839 data.push_back(vertex_half_edge(Point(100, 1), Point(0, 0), -1));
Chris@16	2840 data.push_back(vertex_half_edge(Point(100, 1), Point(101, 101), 1));
Chris@16	2841 data.push_back(vertex_half_edge(Point(101, 101), Point(100, 1), -1));
Chris@16	2842 data.push_back(vertex_half_edge(Point(101, 101), Point(1, 100), 1));
Chris@16	2843
Chris@16	2844 data.push_back(vertex_half_edge(Point(2, 2), Point(10, 2), -1));
Chris@16	2845 data.push_back(vertex_half_edge(Point(2, 2), Point(2, 10), -1));
Chris@16	2846 data.push_back(vertex_half_edge(Point(2, 10), Point(2, 2), 1));
Chris@16	2847 data.push_back(vertex_half_edge(Point(2, 10), Point(10, 10), 1));
Chris@16	2848 data.push_back(vertex_half_edge(Point(10, 2), Point(2, 2), 1));
Chris@16	2849 data.push_back(vertex_half_edge(Point(10, 2), Point(10, 10), 1));
Chris@16	2850 data.push_back(vertex_half_edge(Point(10, 10), Point(10, 2), -1));
Chris@16	2851 data.push_back(vertex_half_edge(Point(10, 10), Point(2, 10), -1));
Chris@16	2852
Chris@16	2853 data.push_back(vertex_half_edge(Point(2, 12), Point(10, 12), -1));
Chris@16	2854 data.push_back(vertex_half_edge(Point(2, 12), Point(2, 22), -1));
Chris@16	2855 data.push_back(vertex_half_edge(Point(2, 22), Point(2, 12), 1));
Chris@16	2856 data.push_back(vertex_half_edge(Point(2, 22), Point(10, 22), 1));
Chris@16	2857 data.push_back(vertex_half_edge(Point(10, 12), Point(2, 12), 1));
Chris@16	2858 data.push_back(vertex_half_edge(Point(10, 12), Point(10, 22), 1));
Chris@16	2859 data.push_back(vertex_half_edge(Point(10, 22), Point(10, 12), -1));
Chris@16	2860 data.push_back(vertex_half_edge(Point(10, 22), Point(2, 22), -1));
Chris@16	2861
Chris@16	2862 polygon_sort(data.begin(), data.end());
Chris@16	2863 pf.scan(polys, data.begin(), data.end());
Chris@16	2864 stdcout << "result size: " << polys.size() << "\n";
Chris@16	2865 for(std::size_t i = 0; i < polys.size(); ++i) {
Chris@16	2866 stdcout << polys[i] << "\n";
Chris@16	2867 }
Chris@16	2868 //pf2.scan(polys2, data.begin(), data.end());
Chris@16	2869 //stdcout << "result size: " << polys2.size() << "\n";
Chris@16	2870 //for(std::size_t i = 0; i < polys2.size(); ++i) {
Chris@16	2871 // stdcout << polys2[i] << "\n";
Chris@16	2872 //}
Chris@16	2873 stdcout << "done testing trapezoid formation\n";
Chris@16	2874 return true;
Chris@16	2875 }
Chris@16	2876
Chris@16	2877 template <typename stream_type>
Chris@16	2878 static inline bool testTrapezoidArbitraryFormationSelfTouch1(stream_type& stdcout) {
Chris@16	2879 stdcout << "testing trapezoid formation self touch 1\n";
Chris@16	2880 trapezoid_arbitrary_formation pf;
Chris@16	2881 std::vector<polygon_data<Unit> > polys;
Chris@16	2882 std::vector<vertex_half_edge> data;
Chris@16	2883 data.push_back(vertex_half_edge(Point(0, 0), Point(10, 0), 1));
Chris@16	2884 data.push_back(vertex_half_edge(Point(0, 0), Point(0, 10), 1));
Chris@16	2885
Chris@16	2886 data.push_back(vertex_half_edge(Point(0, 10), Point(0, 0), -1));
Chris@16	2887 data.push_back(vertex_half_edge(Point(0, 10), Point(5, 10), -1));
Chris@16	2888
Chris@16	2889 data.push_back(vertex_half_edge(Point(10, 0), Point(0, 0), -1));
Chris@16	2890 data.push_back(vertex_half_edge(Point(10, 0), Point(10, 5), -1));
Chris@16	2891
Chris@16	2892 data.push_back(vertex_half_edge(Point(10, 5), Point(10, 0), 1));
Chris@16	2893 data.push_back(vertex_half_edge(Point(10, 5), Point(5, 5), 1));
Chris@16	2894
Chris@16	2895 data.push_back(vertex_half_edge(Point(5, 10), Point(5, 5), 1));
Chris@16	2896 data.push_back(vertex_half_edge(Point(5, 10), Point(0, 10), 1));
Chris@16	2897
Chris@16	2898 data.push_back(vertex_half_edge(Point(5, 2), Point(5, 5), -1));
Chris@16	2899 data.push_back(vertex_half_edge(Point(5, 2), Point(7, 2), -1));
Chris@16	2900
Chris@16	2901 data.push_back(vertex_half_edge(Point(5, 5), Point(5, 10), -1));
Chris@16	2902 data.push_back(vertex_half_edge(Point(5, 5), Point(5, 2), 1));
Chris@16	2903 data.push_back(vertex_half_edge(Point(5, 5), Point(10, 5), -1));
Chris@16	2904 data.push_back(vertex_half_edge(Point(5, 5), Point(7, 2), 1));
Chris@16	2905
Chris@16	2906 data.push_back(vertex_half_edge(Point(7, 2), Point(5, 5), -1));
Chris@16	2907 data.push_back(vertex_half_edge(Point(7, 2), Point(5, 2), 1));
Chris@16	2908
Chris@16	2909 polygon_sort(data.begin(), data.end());
Chris@16	2910 pf.scan(polys, data.begin(), data.end());
Chris@16	2911 stdcout << "result size: " << polys.size() << "\n";
Chris@16	2912 for(std::size_t i = 0; i < polys.size(); ++i) {
Chris@16	2913 stdcout << polys[i] << "\n";
Chris@16	2914 }
Chris@16	2915 stdcout << "done testing trapezoid formation\n";
Chris@16	2916 return true;
Chris@16	2917 }
Chris@16	2918 };
Chris@16	2919
Chris@16	2920 template <typename T>
Chris@16	2921 struct PolyLineArbitraryByConcept<T, polygon_with_holes_concept> { typedef poly_line_arbitrary_polygon_data<T> type; };
Chris@16	2922 template <typename T>
Chris@16	2923 struct PolyLineArbitraryByConcept<T, polygon_concept> { typedef poly_line_arbitrary_hole_data<T> type; };
Chris@16	2924
Chris@16	2925 template <typename T>
Chris@16	2926 struct geometry_concept<poly_line_arbitrary_polygon_data<T> > { typedef polygon_45_with_holes_concept type; };
Chris@16	2927 template <typename T>
Chris@16	2928 struct geometry_concept<poly_line_arbitrary_hole_data<T> > { typedef polygon_45_concept type; };
Chris@16	2929 }
Chris@16	2930 }
Chris@16	2931 #endif

Mercurial > hg > vamp-build-and-test

annotate DEPENDENCIES/generic/include/boost/polygon/detail/polygon_arbitrary_formation.hpp @ 133:4acb5d8d80b6 tip