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

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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_SET_DATA_HPP
Chris@16 9 #define BOOST_POLYGON_POLYGON_SET_DATA_HPP
Chris@16 10 #include "polygon_45_set_data.hpp"
Chris@16 11 #include "polygon_45_set_concept.hpp"
Chris@16 12 #include "polygon_traits.hpp"
Chris@16 13 #include "detail/polygon_arbitrary_formation.hpp"
Chris@16 14
Chris@16 15 namespace boost { namespace polygon {
Chris@16 16
Chris@16 17
Chris@16 18 // utility function to round coordinate types down
Chris@16 19 // rounds down for both negative and positive numbers
Chris@16 20 // intended really for integer type T (does not make sense for float)
Chris@16 21 template <typename T>
Chris@16 22 static inline T round_down(double val) {
Chris@16 23 T rounded_val = (T)(val);
Chris@16 24 if(val < (double)rounded_val)
Chris@16 25 --rounded_val;
Chris@16 26 return rounded_val;
Chris@16 27 }
Chris@16 28 template <typename T>
Chris@16 29 static inline point_data<T> round_down(point_data<double> v) {
Chris@16 30 return point_data<T>(round_down<T>(v.x()),round_down<T>(v.y()));
Chris@16 31 }
Chris@16 32
Chris@16 33
Chris@16 34
Chris@16 35 //foward declare view
Chris@16 36 template <typename ltype, typename rtype, int op_type> class polygon_set_view;
Chris@16 37
Chris@16 38 template <typename T>
Chris@16 39 class polygon_set_data {
Chris@16 40 public:
Chris@16 41 typedef T coordinate_type;
Chris@16 42 typedef point_data<T> point_type;
Chris@16 43 typedef std::pair<point_type, point_type> edge_type;
Chris@16 44 typedef std::pair<edge_type, int> element_type;
Chris@16 45 typedef std::vector<element_type> value_type;
Chris@16 46 typedef typename value_type::const_iterator iterator_type;
Chris@16 47 typedef polygon_set_data operator_arg_type;
Chris@16 48
Chris@16 49 // default constructor
Chris@16 50 inline polygon_set_data() : data_(), dirty_(false), unsorted_(false), is_45_(true) {}
Chris@16 51
Chris@16 52 // constructor from an iterator pair over edge data
Chris@16 53 template <typename iT>
Chris@16 54 inline polygon_set_data(iT input_begin, iT input_end) : data_(), dirty_(false), unsorted_(false), is_45_(true) {
Chris@16 55 for( ; input_begin != input_end; ++input_begin) { insert(*input_begin); }
Chris@16 56 }
Chris@16 57
Chris@16 58 // copy constructor
Chris@16 59 inline polygon_set_data(const polygon_set_data& that) :
Chris@16 60 data_(that.data_), dirty_(that.dirty_), unsorted_(that.unsorted_), is_45_(that.is_45_) {}
Chris@16 61
Chris@16 62 // copy constructor
Chris@16 63 template <typename ltype, typename rtype, int op_type>
Chris@16 64 inline polygon_set_data(const polygon_set_view<ltype, rtype, op_type>& that);
Chris@16 65
Chris@16 66 // destructor
Chris@16 67 inline ~polygon_set_data() {}
Chris@16 68
Chris@16 69 // assignement operator
Chris@16 70 inline polygon_set_data& operator=(const polygon_set_data& that) {
Chris@16 71 if(this == &that) return *this;
Chris@16 72 data_ = that.data_;
Chris@16 73 dirty_ = that.dirty_;
Chris@16 74 unsorted_ = that.unsorted_;
Chris@16 75 is_45_ = that.is_45_;
Chris@16 76 return *this;
Chris@16 77 }
Chris@16 78
Chris@16 79 template <typename ltype, typename rtype, int op_type>
Chris@16 80 inline polygon_set_data& operator=(const polygon_set_view<ltype, rtype, op_type>& geometry) {
Chris@16 81 (*this) = geometry.value();
Chris@16 82 dirty_ = false;
Chris@16 83 unsorted_ = false;
Chris@16 84 return *this;
Chris@16 85 }
Chris@16 86
Chris@16 87 template <typename geometry_object>
Chris@16 88 inline polygon_set_data& operator=(const geometry_object& geometry) {
Chris@16 89 data_.clear();
Chris@16 90 insert(geometry);
Chris@16 91 return *this;
Chris@16 92 }
Chris@16 93
Chris@16 94
Chris@16 95 // insert iterator range
Chris@16 96 inline void insert(iterator_type input_begin, iterator_type input_end, bool is_hole = false) {
Chris@16 97 if(input_begin == input_end || (!data_.empty() && &(*input_begin) == &(*(data_.begin())))) return;
Chris@16 98 dirty_ = true;
Chris@16 99 unsorted_ = true;
Chris@16 100 while(input_begin != input_end) {
Chris@16 101 insert(*input_begin, is_hole);
Chris@16 102 ++input_begin;
Chris@16 103 }
Chris@16 104 }
Chris@16 105
Chris@16 106 // insert iterator range
Chris@16 107 template <typename iT>
Chris@16 108 inline void insert(iT input_begin, iT input_end, bool is_hole = false) {
Chris@16 109 if(input_begin == input_end) return;
Chris@16 110 for(; input_begin != input_end; ++input_begin) {
Chris@16 111 insert(*input_begin, is_hole);
Chris@16 112 }
Chris@16 113 }
Chris@16 114
Chris@16 115 template <typename geometry_type>
Chris@16 116 inline void insert(const geometry_type& geometry_object, bool is_hole = false) {
Chris@16 117 insert(geometry_object, is_hole, typename geometry_concept<geometry_type>::type());
Chris@16 118 }
Chris@16 119
Chris@16 120 template <typename polygon_type>
Chris@16 121 inline void insert(const polygon_type& polygon_object, bool is_hole, polygon_concept ) {
Chris@16 122 insert_vertex_sequence(begin_points(polygon_object), end_points(polygon_object), winding(polygon_object), is_hole);
Chris@16 123 }
Chris@16 124
Chris@16 125 inline void insert(const polygon_set_data& ps, bool is_hole = false) {
Chris@16 126 insert(ps.data_.begin(), ps.data_.end(), is_hole);
Chris@16 127 }
Chris@16 128
Chris@16 129 template <typename polygon_45_set_type>
Chris@16 130 inline void insert(const polygon_45_set_type& ps, bool is_hole, polygon_45_set_concept) {
Chris@16 131 std::vector<polygon_45_with_holes_data<typename polygon_45_set_traits<polygon_45_set_type>::coordinate_type> > polys;
Chris@16 132 assign(polys, ps);
Chris@16 133 insert(polys.begin(), polys.end(), is_hole);
Chris@16 134 }
Chris@16 135
Chris@16 136 template <typename polygon_90_set_type>
Chris@16 137 inline void insert(const polygon_90_set_type& ps, bool is_hole, polygon_90_set_concept) {
Chris@16 138 std::vector<polygon_90_with_holes_data<typename polygon_90_set_traits<polygon_90_set_type>::coordinate_type> > polys;
Chris@16 139 assign(polys, ps);
Chris@16 140 insert(polys.begin(), polys.end(), is_hole);
Chris@16 141 }
Chris@16 142
Chris@16 143 template <typename polygon_type>
Chris@16 144 inline void insert(const polygon_type& polygon_object, bool is_hole, polygon_45_concept ) {
Chris@16 145 insert(polygon_object, is_hole, polygon_concept()); }
Chris@16 146
Chris@16 147 template <typename polygon_type>
Chris@16 148 inline void insert(const polygon_type& polygon_object, bool is_hole, polygon_90_concept ) {
Chris@16 149 insert(polygon_object, is_hole, polygon_concept()); }
Chris@16 150
Chris@16 151 template <typename polygon_with_holes_type>
Chris@16 152 inline void insert(const polygon_with_holes_type& polygon_with_holes_object, bool is_hole,
Chris@16 153 polygon_with_holes_concept ) {
Chris@16 154 insert(polygon_with_holes_object, is_hole, polygon_concept());
Chris@16 155 for(typename polygon_with_holes_traits<polygon_with_holes_type>::iterator_holes_type itr =
Chris@16 156 begin_holes(polygon_with_holes_object);
Chris@16 157 itr != end_holes(polygon_with_holes_object); ++itr) {
Chris@16 158 insert(*itr, !is_hole, polygon_concept());
Chris@16 159 }
Chris@16 160 }
Chris@16 161
Chris@16 162 template <typename polygon_with_holes_type>
Chris@16 163 inline void insert(const polygon_with_holes_type& polygon_with_holes_object, bool is_hole,
Chris@16 164 polygon_45_with_holes_concept ) {
Chris@16 165 insert(polygon_with_holes_object, is_hole, polygon_with_holes_concept()); }
Chris@16 166
Chris@16 167 template <typename polygon_with_holes_type>
Chris@16 168 inline void insert(const polygon_with_holes_type& polygon_with_holes_object, bool is_hole,
Chris@16 169 polygon_90_with_holes_concept ) {
Chris@16 170 insert(polygon_with_holes_object, is_hole, polygon_with_holes_concept()); }
Chris@16 171
Chris@16 172 template <typename rectangle_type>
Chris@16 173 inline void insert(const rectangle_type& rectangle_object, bool is_hole, rectangle_concept ) {
Chris@16 174 polygon_90_data<coordinate_type> poly;
Chris@16 175 assign(poly, rectangle_object);
Chris@16 176 insert(poly, is_hole, polygon_concept());
Chris@16 177 }
Chris@16 178
Chris@16 179 inline void insert_clean(const element_type& edge, bool is_hole = false) {
Chris@16 180 if( ! scanline_base<coordinate_type>::is_45_degree(edge.first) &&
Chris@16 181 ! scanline_base<coordinate_type>::is_horizontal(edge.first) &&
Chris@16 182 ! scanline_base<coordinate_type>::is_vertical(edge.first) ) is_45_ = false;
Chris@16 183 data_.push_back(edge);
Chris@16 184 if(data_.back().first.second < data_.back().first.first) {
Chris@16 185 std::swap(data_.back().first.second, data_.back().first.first);
Chris@16 186 data_.back().second *= -1;
Chris@16 187 }
Chris@16 188 if(is_hole)
Chris@16 189 data_.back().second *= -1;
Chris@16 190 }
Chris@16 191
Chris@16 192 inline void insert(const element_type& edge, bool is_hole = false) {
Chris@16 193 insert_clean(edge, is_hole);
Chris@16 194 dirty_ = true;
Chris@16 195 unsorted_ = true;
Chris@16 196 }
Chris@16 197
Chris@16 198 template <class iT>
Chris@16 199 inline void insert_vertex_sequence(iT begin_vertex, iT end_vertex, direction_1d winding, bool is_hole) {
Chris@101 200 if (begin_vertex == end_vertex) {
Chris@101 201 // No edges to insert.
Chris@101 202 return;
Chris@16 203 }
Chris@101 204 // Current edge endpoints.
Chris@101 205 iT vertex0 = begin_vertex;
Chris@101 206 iT vertex1 = begin_vertex;
Chris@101 207 if (++vertex1 == end_vertex) {
Chris@101 208 // No edges to insert.
Chris@101 209 return;
Chris@101 210 }
Chris@101 211 int wmultiplier = (winding == COUNTERCLOCKWISE) ? 1 : -1;
Chris@101 212 if (is_hole) {
Chris@101 213 wmultiplier = -wmultiplier;
Chris@101 214 }
Chris@101 215 dirty_ = true;
Chris@101 216 unsorted_ = true;
Chris@101 217 while (vertex0 != end_vertex) {
Chris@101 218 point_type p0, p1;
Chris@101 219 assign(p0, *vertex0);
Chris@101 220 assign(p1, *vertex1);
Chris@101 221 if (p0 != p1) {
Chris@101 222 int hmultiplier = (p0.get(HORIZONTAL) == p1.get(HORIZONTAL)) ? -1 : 1;
Chris@101 223 element_type elem(edge_type(p0, p1), hmultiplier * wmultiplier);
Chris@16 224 insert_clean(elem);
Chris@16 225 }
Chris@101 226 ++vertex0;
Chris@101 227 ++vertex1;
Chris@101 228 if (vertex1 == end_vertex) {
Chris@101 229 vertex1 = begin_vertex;
Chris@101 230 }
Chris@16 231 }
Chris@16 232 }
Chris@16 233
Chris@16 234 template <typename output_container>
Chris@16 235 inline void get(output_container& output) const {
Chris@16 236 get_dispatch(output, typename geometry_concept<typename output_container::value_type>::type());
Chris@16 237 }
Chris@16 238
Chris@16 239 // append to the container cT with polygons of three or four verticies
Chris@16 240 // slicing orientation is vertical
Chris@16 241 template <class cT>
Chris@16 242 void get_trapezoids(cT& container) const {
Chris@16 243 clean();
Chris@16 244 trapezoid_arbitrary_formation<coordinate_type> pf;
Chris@16 245 typedef typename polygon_arbitrary_formation<coordinate_type>::vertex_half_edge vertex_half_edge;
Chris@16 246 std::vector<vertex_half_edge> data;
Chris@16 247 for(iterator_type itr = data_.begin(); itr != data_.end(); ++itr){
Chris@16 248 data.push_back(vertex_half_edge((*itr).first.first, (*itr).first.second, (*itr).second));
Chris@16 249 data.push_back(vertex_half_edge((*itr).first.second, (*itr).first.first, -1 * (*itr).second));
Chris@16 250 }
Chris@16 251 polygon_sort(data.begin(), data.end());
Chris@16 252 pf.scan(container, data.begin(), data.end());
Chris@16 253 //std::cout << "DONE FORMING POLYGONS\n";
Chris@16 254 }
Chris@16 255
Chris@16 256 // append to the container cT with polygons of three or four verticies
Chris@16 257 template <class cT>
Chris@16 258 void get_trapezoids(cT& container, orientation_2d slicing_orientation) const {
Chris@16 259 if(slicing_orientation == VERTICAL) {
Chris@16 260 get_trapezoids(container);
Chris@16 261 } else {
Chris@16 262 polygon_set_data<T> ps(*this);
Chris@16 263 ps.transform(axis_transformation(axis_transformation::SWAP_XY));
Chris@16 264 cT result;
Chris@16 265 ps.get_trapezoids(result);
Chris@16 266 for(typename cT::iterator itr = result.begin(); itr != result.end(); ++itr) {
Chris@16 267 ::boost::polygon::transform(*itr, axis_transformation(axis_transformation::SWAP_XY));
Chris@16 268 }
Chris@16 269 container.insert(container.end(), result.begin(), result.end());
Chris@16 270 }
Chris@16 271 }
Chris@16 272
Chris@16 273 // equivalence operator
Chris@16 274 inline bool operator==(const polygon_set_data& p) const;
Chris@101 275
Chris@16 276 // inequivalence operator
Chris@16 277 inline bool operator!=(const polygon_set_data& p) const {
Chris@16 278 return !((*this) == p);
Chris@16 279 }
Chris@16 280
Chris@16 281 // get iterator to begin vertex data
Chris@16 282 inline iterator_type begin() const {
Chris@16 283 return data_.begin();
Chris@16 284 }
Chris@16 285
Chris@16 286 // get iterator to end vertex data
Chris@16 287 inline iterator_type end() const {
Chris@16 288 return data_.end();
Chris@16 289 }
Chris@16 290
Chris@16 291 const value_type& value() const {
Chris@16 292 return data_;
Chris@16 293 }
Chris@16 294
Chris@16 295 // clear the contents of the polygon_set_data
Chris@16 296 inline void clear() { data_.clear(); dirty_ = unsorted_ = false; }
Chris@16 297
Chris@16 298 // find out if Polygon set is empty
Chris@16 299 inline bool empty() const { return data_.empty(); }
Chris@16 300
Chris@16 301 // get the Polygon set size in vertices
Chris@16 302 inline std::size_t size() const { clean(); return data_.size(); }
Chris@16 303
Chris@16 304 // get the current Polygon set capacity in vertices
Chris@16 305 inline std::size_t capacity() const { return data_.capacity(); }
Chris@16 306
Chris@16 307 // reserve size of polygon set in vertices
Chris@16 308 inline void reserve(std::size_t size) { return data_.reserve(size); }
Chris@16 309
Chris@16 310 // find out if Polygon set is sorted
Chris@16 311 inline bool sorted() const { return !unsorted_; }
Chris@16 312
Chris@16 313 // find out if Polygon set is clean
Chris@16 314 inline bool dirty() const { return dirty_; }
Chris@16 315
Chris@16 316 void clean() const;
Chris@16 317
Chris@16 318 void sort() const{
Chris@16 319 if(unsorted_) {
Chris@16 320 polygon_sort(data_.begin(), data_.end());
Chris@16 321 unsorted_ = false;
Chris@16 322 }
Chris@16 323 }
Chris@16 324
Chris@16 325 template <typename input_iterator_type>
Chris@16 326 void set(input_iterator_type input_begin, input_iterator_type input_end) {
Chris@16 327 clear();
Chris@16 328 reserve(std::distance(input_begin,input_end));
Chris@16 329 insert(input_begin, input_end);
Chris@16 330 dirty_ = true;
Chris@16 331 unsorted_ = true;
Chris@16 332 }
Chris@16 333
Chris@16 334 void set(const value_type& value) {
Chris@16 335 data_ = value;
Chris@16 336 dirty_ = true;
Chris@16 337 unsorted_ = true;
Chris@16 338 }
Chris@16 339
Chris@16 340 template <typename rectangle_type>
Chris@16 341 bool extents(rectangle_type& rect) {
Chris@16 342 clean();
Chris@16 343 if(empty()) return false;
Chris@16 344 bool first_iteration = true;
Chris@16 345 for(iterator_type itr = begin();
Chris@16 346 itr != end(); ++itr) {
Chris@16 347 rectangle_type edge_box;
Chris@16 348 set_points(edge_box, (*itr).first.first, (*itr).first.second);
Chris@16 349 if(first_iteration)
Chris@16 350 rect = edge_box;
Chris@16 351 else
Chris@16 352 encompass(rect, edge_box);
Chris@16 353 first_iteration = false;
Chris@16 354 }
Chris@16 355 return true;
Chris@16 356 }
Chris@16 357
Chris@16 358 inline polygon_set_data&
Chris@16 359 resize(coordinate_type resizing, bool corner_fill_arc = false, unsigned int num_circle_segments=0);
Chris@16 360
Chris@16 361 template <typename transform_type>
Chris@16 362 inline polygon_set_data&
Chris@16 363 transform(const transform_type& tr) {
Chris@16 364 std::vector<polygon_with_holes_data<T> > polys;
Chris@16 365 get(polys);
Chris@16 366 clear();
Chris@16 367 for(std::size_t i = 0 ; i < polys.size(); ++i) {
Chris@16 368 ::boost::polygon::transform(polys[i], tr);
Chris@16 369 insert(polys[i]);
Chris@16 370 }
Chris@16 371 unsorted_ = true;
Chris@16 372 dirty_ = true;
Chris@16 373 return *this;
Chris@16 374 }
Chris@16 375
Chris@16 376 inline polygon_set_data&
Chris@16 377 scale_up(typename coordinate_traits<coordinate_type>::unsigned_area_type factor) {
Chris@16 378 for(typename value_type::iterator itr = data_.begin(); itr != data_.end(); ++itr) {
Chris@16 379 ::boost::polygon::scale_up((*itr).first.first, factor);
Chris@16 380 ::boost::polygon::scale_up((*itr).first.second, factor);
Chris@16 381 }
Chris@16 382 return *this;
Chris@16 383 }
Chris@16 384
Chris@16 385 inline polygon_set_data&
Chris@16 386 scale_down(typename coordinate_traits<coordinate_type>::unsigned_area_type factor) {
Chris@16 387 for(typename value_type::iterator itr = data_.begin(); itr != data_.end(); ++itr) {
Chris@16 388 bool vb = (*itr).first.first.x() == (*itr).first.second.x();
Chris@16 389 ::boost::polygon::scale_down((*itr).first.first, factor);
Chris@16 390 ::boost::polygon::scale_down((*itr).first.second, factor);
Chris@16 391 bool va = (*itr).first.first.x() == (*itr).first.second.x();
Chris@16 392 if(!vb && va) {
Chris@16 393 (*itr).second *= -1;
Chris@16 394 }
Chris@16 395 }
Chris@16 396 unsorted_ = true;
Chris@16 397 dirty_ = true;
Chris@16 398 return *this;
Chris@16 399 }
Chris@16 400
Chris@16 401 template <typename scaling_type>
Chris@16 402 inline polygon_set_data& scale(polygon_set_data& polygon_set,
Chris@16 403 const scaling_type& scaling) {
Chris@16 404 for(typename value_type::iterator itr = begin(); itr != end(); ++itr) {
Chris@16 405 bool vb = (*itr).first.first.x() == (*itr).first.second.x();
Chris@16 406 ::boost::polygon::scale((*itr).first.first, scaling);
Chris@16 407 ::boost::polygon::scale((*itr).first.second, scaling);
Chris@16 408 bool va = (*itr).first.first.x() == (*itr).first.second.x();
Chris@16 409 if(!vb && va) {
Chris@16 410 (*itr).second *= -1;
Chris@16 411 }
Chris@16 412 }
Chris@16 413 unsorted_ = true;
Chris@16 414 dirty_ = true;
Chris@16 415 return *this;
Chris@16 416 }
Chris@16 417
Chris@16 418 static inline void compute_offset_edge(point_data<long double>& pt1, point_data<long double>& pt2,
Chris@16 419 const point_data<long double>& prev_pt,
Chris@16 420 const point_data<long double>& current_pt,
Chris@16 421 long double distance, int multiplier) {
Chris@16 422 long double dx = current_pt.x() - prev_pt.x();
Chris@16 423 long double dy = current_pt.y() - prev_pt.y();
Chris@16 424 long double edge_length = std::sqrt(dx*dx + dy*dy);
Chris@16 425 long double dnx = dy;
Chris@16 426 long double dny = -dx;
Chris@16 427 dnx = dnx * (long double)distance / edge_length;
Chris@16 428 dny = dny * (long double)distance / edge_length;
Chris@16 429 pt1.x(prev_pt.x() + (long double)dnx * (long double)multiplier);
Chris@16 430 pt2.x(current_pt.x() + (long double)dnx * (long double)multiplier);
Chris@16 431 pt1.y(prev_pt.y() + (long double)dny * (long double)multiplier);
Chris@16 432 pt2.y(current_pt.y() + (long double)dny * (long double)multiplier);
Chris@16 433 }
Chris@16 434
Chris@16 435 static inline void modify_pt(point_data<coordinate_type>& pt, const point_data<coordinate_type>& prev_pt,
Chris@16 436 const point_data<coordinate_type>& current_pt, const point_data<coordinate_type>& next_pt,
Chris@16 437 coordinate_type distance, coordinate_type multiplier) {
Chris@16 438 std::pair<point_data<long double>, point_data<long double> > he1, he2;
Chris@16 439 he1.first.x((long double)(prev_pt.x()));
Chris@16 440 he1.first.y((long double)(prev_pt.y()));
Chris@16 441 he1.second.x((long double)(current_pt.x()));
Chris@16 442 he1.second.y((long double)(current_pt.y()));
Chris@16 443 he2.first.x((long double)(current_pt.x()));
Chris@16 444 he2.first.y((long double)(current_pt.y()));
Chris@16 445 he2.second.x((long double)(next_pt.x()));
Chris@16 446 he2.second.y((long double)(next_pt.y()));
Chris@16 447 compute_offset_edge(he1.first, he1.second, prev_pt, current_pt, distance, multiplier);
Chris@16 448 compute_offset_edge(he2.first, he2.second, current_pt, next_pt, distance, multiplier);
Chris@16 449 typedef scanline_base<long double>::compute_intersection_pack pack;
Chris@16 450 point_data<long double> rpt;
Chris@16 451 point_data<long double> bisectorpt((he1.second.x()+he2.first.x())/2,
Chris@16 452 (he1.second.y()+he2.first.y())/2);
Chris@16 453 point_data<long double> orig_pt((long double)pt.x(), (long double)pt.y());
Chris@16 454 if(euclidean_distance(bisectorpt, orig_pt) < distance/2) {
Chris@16 455 if(!pack::compute_lazy_intersection(rpt, he1, he2, true, false)) {
Chris@16 456 rpt = he1.second; //colinear offset edges use shared point
Chris@16 457 }
Chris@16 458 } else {
Chris@16 459 if(!pack::compute_lazy_intersection(rpt, he1, std::pair<point_data<long double>, point_data<long double> >(orig_pt, bisectorpt), true, false)) {
Chris@16 460 rpt = he1.second; //colinear offset edges use shared point
Chris@16 461 }
Chris@16 462 }
Chris@16 463 pt.x((coordinate_type)(std::floor(rpt.x()+0.5)));
Chris@16 464 pt.y((coordinate_type)(std::floor(rpt.y()+0.5)));
Chris@16 465 }
Chris@16 466
Chris@16 467 static void resize_poly_up(std::vector<point_data<coordinate_type> >& poly, coordinate_type distance, coordinate_type multiplier) {
Chris@16 468 point_data<coordinate_type> first_pt = poly[0];
Chris@16 469 point_data<coordinate_type> second_pt = poly[1];
Chris@16 470 point_data<coordinate_type> prev_pt = poly[0];
Chris@16 471 point_data<coordinate_type> current_pt = poly[1];
Chris@16 472 for(std::size_t i = 2; i < poly.size()-1; ++i) {
Chris@16 473 point_data<coordinate_type> next_pt = poly[i];
Chris@16 474 modify_pt(poly[i-1], prev_pt, current_pt, next_pt, distance, multiplier);
Chris@16 475 prev_pt = current_pt;
Chris@16 476 current_pt = next_pt;
Chris@16 477 }
Chris@16 478 point_data<coordinate_type> next_pt = first_pt;
Chris@16 479 modify_pt(poly[poly.size()-2], prev_pt, current_pt, next_pt, distance, multiplier);
Chris@16 480 prev_pt = current_pt;
Chris@16 481 current_pt = next_pt;
Chris@16 482 next_pt = second_pt;
Chris@16 483 modify_pt(poly[0], prev_pt, current_pt, next_pt, distance, multiplier);
Chris@16 484 poly.back() = poly.front();
Chris@16 485 }
Chris@16 486 static bool resize_poly_down(std::vector<point_data<coordinate_type> >& poly, coordinate_type distance, coordinate_type multiplier) {
Chris@16 487 std::vector<point_data<coordinate_type> > orig_poly(poly);
Chris@16 488 rectangle_data<coordinate_type> extents_rectangle;
Chris@16 489 set_points(extents_rectangle, poly[0], poly[0]);
Chris@16 490 point_data<coordinate_type> first_pt = poly[0];
Chris@16 491 point_data<coordinate_type> second_pt = poly[1];
Chris@16 492 point_data<coordinate_type> prev_pt = poly[0];
Chris@16 493 point_data<coordinate_type> current_pt = poly[1];
Chris@16 494 encompass(extents_rectangle, current_pt);
Chris@16 495 for(std::size_t i = 2; i < poly.size()-1; ++i) {
Chris@16 496 point_data<coordinate_type> next_pt = poly[i];
Chris@16 497 encompass(extents_rectangle, next_pt);
Chris@16 498 modify_pt(poly[i-1], prev_pt, current_pt, next_pt, distance, multiplier);
Chris@16 499 prev_pt = current_pt;
Chris@16 500 current_pt = next_pt;
Chris@16 501 }
Chris@16 502 if(delta(extents_rectangle, HORIZONTAL) <= std::abs(2*distance))
Chris@16 503 return false;
Chris@16 504 if(delta(extents_rectangle, VERTICAL) <= std::abs(2*distance))
Chris@16 505 return false;
Chris@16 506 point_data<coordinate_type> next_pt = first_pt;
Chris@16 507 modify_pt(poly[poly.size()-2], prev_pt, current_pt, next_pt, distance, multiplier);
Chris@16 508 prev_pt = current_pt;
Chris@16 509 current_pt = next_pt;
Chris@16 510 next_pt = second_pt;
Chris@16 511 modify_pt(poly[0], prev_pt, current_pt, next_pt, distance, multiplier);
Chris@16 512 poly.back() = poly.front();
Chris@16 513 //if the line segments formed between orignial and new points cross for an edge that edge inverts
Chris@16 514 //if all edges invert the polygon should be discarded
Chris@16 515 //if even one edge does not invert return true because the polygon is valid
Chris@16 516 bool non_inverting_edge = false;
Chris@16 517 for(std::size_t i = 1; i < poly.size(); ++i) {
Chris@16 518 std::pair<point_data<coordinate_type>, point_data<coordinate_type> >
Chris@16 519 he1(poly[i], orig_poly[i]),
Chris@16 520 he2(poly[i-1], orig_poly[i-1]);
Chris@16 521 if(!scanline_base<coordinate_type>::intersects(he1, he2)) {
Chris@16 522 non_inverting_edge = true;
Chris@16 523 break;
Chris@16 524 }
Chris@16 525 }
Chris@16 526 return non_inverting_edge;
Chris@16 527 }
Chris@16 528
Chris@16 529 polygon_set_data&
Chris@16 530 bloat(typename coordinate_traits<coordinate_type>::unsigned_area_type distance) {
Chris@16 531 std::list<polygon_with_holes_data<coordinate_type> > polys;
Chris@16 532 get(polys);
Chris@16 533 clear();
Chris@16 534 for(typename std::list<polygon_with_holes_data<coordinate_type> >::iterator itr = polys.begin();
Chris@16 535 itr != polys.end(); ++itr) {
Chris@16 536 resize_poly_up((*itr).self_.coords_, (coordinate_type)distance, (coordinate_type)1);
Chris@16 537 insert_vertex_sequence((*itr).self_.begin(), (*itr).self_.end(), COUNTERCLOCKWISE, false); //inserts without holes
Chris@16 538 for(typename std::list<polygon_data<coordinate_type> >::iterator itrh = (*itr).holes_.begin();
Chris@16 539 itrh != (*itr).holes_.end(); ++itrh) {
Chris@16 540 if(resize_poly_down((*itrh).coords_, (coordinate_type)distance, (coordinate_type)1)) {
Chris@16 541 insert_vertex_sequence((*itrh).coords_.begin(), (*itrh).coords_.end(), CLOCKWISE, true);
Chris@16 542 }
Chris@16 543 }
Chris@16 544 }
Chris@16 545 return *this;
Chris@16 546 }
Chris@16 547
Chris@16 548 polygon_set_data&
Chris@16 549 shrink(typename coordinate_traits<coordinate_type>::unsigned_area_type distance) {
Chris@16 550 std::list<polygon_with_holes_data<coordinate_type> > polys;
Chris@16 551 get(polys);
Chris@16 552 clear();
Chris@16 553 for(typename std::list<polygon_with_holes_data<coordinate_type> >::iterator itr = polys.begin();
Chris@16 554 itr != polys.end(); ++itr) {
Chris@16 555 if(resize_poly_down((*itr).self_.coords_, (coordinate_type)distance, (coordinate_type)-1)) {
Chris@16 556 insert_vertex_sequence((*itr).self_.begin(), (*itr).self_.end(), COUNTERCLOCKWISE, false); //inserts without holes
Chris@16 557 for(typename std::list<polygon_data<coordinate_type> >::iterator itrh = (*itr).holes_.begin();
Chris@16 558 itrh != (*itr).holes_.end(); ++itrh) {
Chris@16 559 resize_poly_up((*itrh).coords_, (coordinate_type)distance, (coordinate_type)-1);
Chris@16 560 insert_vertex_sequence((*itrh).coords_.begin(), (*itrh).coords_.end(), CLOCKWISE, true);
Chris@16 561 }
Chris@16 562 }
Chris@16 563 }
Chris@16 564 return *this;
Chris@16 565 }
Chris@16 566
Chris@16 567 // TODO:: should be private
Chris@16 568 template <typename geometry_type>
Chris@16 569 inline polygon_set_data&
Chris@16 570 insert_with_resize(const geometry_type& poly, coordinate_type resizing, bool corner_fill_arc=false, unsigned int num_circle_segments=0, bool hole = false) {
Chris@16 571 return insert_with_resize_dispatch(poly, resizing, corner_fill_arc, num_circle_segments, hole, typename geometry_concept<geometry_type>::type());
Chris@16 572 }
Chris@16 573
Chris@16 574 template <typename geometry_type>
Chris@16 575 inline polygon_set_data&
Chris@16 576 insert_with_resize_dispatch(const geometry_type& poly, coordinate_type resizing, bool corner_fill_arc, unsigned int num_circle_segments, bool hole,
Chris@16 577 polygon_with_holes_concept tag) {
Chris@16 578 insert_with_resize_dispatch(poly, resizing, corner_fill_arc, num_circle_segments, hole, polygon_concept());
Chris@16 579 for(typename polygon_with_holes_traits<geometry_type>::iterator_holes_type itr =
Chris@16 580 begin_holes(poly); itr != end_holes(poly);
Chris@16 581 ++itr) {
Chris@16 582 insert_with_resize_dispatch(*itr, resizing, corner_fill_arc, num_circle_segments, !hole, polygon_concept());
Chris@16 583 }
Chris@16 584 return *this;
Chris@16 585 }
Chris@16 586
Chris@16 587 template <typename geometry_type>
Chris@16 588 inline polygon_set_data&
Chris@16 589 insert_with_resize_dispatch(const geometry_type& poly, coordinate_type resizing, bool corner_fill_arc, unsigned int num_circle_segments, bool hole,
Chris@16 590 polygon_concept tag) {
Chris@16 591
Chris@16 592 if (resizing==0)
Chris@16 593 return *this;
Chris@16 594
Chris@16 595
Chris@16 596 // one dimensional used to store CCW/CW flag
Chris@16 597 //direction_1d wdir = winding(poly);
Chris@16 598 // LOW==CLOCKWISE just faster to type
Chris@16 599 // so > 0 is CCW
Chris@16 600 //int multiplier = wdir == LOW ? -1 : 1;
Chris@16 601 //std::cout<<" multiplier : "<<multiplier<<std::endl;
Chris@16 602 //if(hole) resizing *= -1;
Chris@16 603 direction_1d resize_wdir = resizing>0?COUNTERCLOCKWISE:CLOCKWISE;
Chris@16 604
Chris@16 605 typedef typename polygon_data<T>::iterator_type piterator;
Chris@16 606 piterator first, second, third, end, real_end;
Chris@16 607 real_end = end_points(poly);
Chris@16 608 third = begin_points(poly);
Chris@16 609 first = third;
Chris@16 610 if(first == real_end) return *this;
Chris@16 611 ++third;
Chris@16 612 if(third == real_end) return *this;
Chris@16 613 second = end = third;
Chris@16 614 ++third;
Chris@16 615 if(third == real_end) return *this;
Chris@16 616
Chris@16 617 // for 1st corner
Chris@16 618 std::vector<point_data<T> > first_pts;
Chris@16 619 std::vector<point_data<T> > all_pts;
Chris@16 620 direction_1d first_wdir = CLOCKWISE;
Chris@16 621
Chris@16 622 // for all corners
Chris@16 623 polygon_set_data<T> sizingSet;
Chris@16 624 bool sizing_sign = resizing<0;
Chris@16 625 bool prev_concave = true;
Chris@16 626 point_data<T> prev_point;
Chris@16 627 //int iCtr=0;
Chris@16 628
Chris@16 629
Chris@16 630 //insert minkofski shapes on edges and corners
Chris@16 631 do { // REAL WORK IS HERE
Chris@16 632
Chris@16 633
Chris@16 634 //first, second and third point to points in correct CCW order
Chris@16 635 // check if convex or concave case
Chris@16 636 point_data<coordinate_type> normal1( second->y()-first->y(), first->x()-second->x());
Chris@16 637 point_data<coordinate_type> normal2( third->y()-second->y(), second->x()-third->x());
Chris@16 638 double direction = normal1.x()*normal2.y()- normal2.x()*normal1.y();
Chris@16 639 bool convex = direction>0;
Chris@16 640
Chris@16 641 bool treat_as_concave = !convex;
Chris@16 642 if(sizing_sign)
Chris@16 643 treat_as_concave = convex;
Chris@16 644 point_data<double> v;
Chris@16 645 assign(v, normal1);
Chris@16 646 double s2 = (v.x()*v.x()+v.y()*v.y());
Chris@16 647 double s = std::sqrt(s2)/resizing;
Chris@16 648 v = point_data<double>(v.x()/s,v.y()/s);
Chris@16 649 point_data<T> curr_prev;
Chris@16 650 if (prev_concave)
Chris@16 651 //TODO missing round_down()
Chris@16 652 curr_prev = point_data<T>(first->x()+v.x(),first->y()+v.y());
Chris@16 653 else
Chris@16 654 curr_prev = prev_point;
Chris@16 655
Chris@16 656 // around concave corners - insert rectangle
Chris@16 657 // if previous corner is concave it's point info may be ignored
Chris@16 658 if ( treat_as_concave) {
Chris@16 659 std::vector<point_data<T> > pts;
Chris@16 660
Chris@16 661 pts.push_back(point_data<T>(second->x()+v.x(),second->y()+v.y()));
Chris@16 662 pts.push_back(*second);
Chris@16 663 pts.push_back(*first);
Chris@16 664 pts.push_back(point_data<T>(curr_prev));
Chris@16 665 if (first_pts.size()){
Chris@16 666 sizingSet.insert_vertex_sequence(pts.begin(),pts.end(), resize_wdir,false);
Chris@16 667 }else {
Chris@16 668 first_pts=pts;
Chris@16 669 first_wdir = resize_wdir;
Chris@16 670 }
Chris@16 671 } else {
Chris@16 672
Chris@16 673 // add either intersection_quad or pie_shape, based on corner_fill_arc option
Chris@16 674 // for convex corner (convexity depends on sign of resizing, whether we shrink or grow)
Chris@16 675 std::vector< std::vector<point_data<T> > > pts;
Chris@16 676 direction_1d winding;
Chris@16 677 winding = convex?COUNTERCLOCKWISE:CLOCKWISE;
Chris@16 678 if (make_resizing_vertex_list(pts, curr_prev, prev_concave, *first, *second, *third, resizing
Chris@16 679 , num_circle_segments, corner_fill_arc))
Chris@16 680 {
Chris@16 681 if (first_pts.size()) {
Chris@16 682 for (int i=0; i<pts.size(); i++) {
Chris@16 683 sizingSet.insert_vertex_sequence(pts[i].begin(),pts[i].end(),winding,false);
Chris@16 684 }
Chris@16 685
Chris@16 686 } else {
Chris@16 687 first_pts = pts[0];
Chris@16 688 first_wdir = resize_wdir;
Chris@16 689 for (int i=1; i<pts.size(); i++) {
Chris@16 690 sizingSet.insert_vertex_sequence(pts[i].begin(),pts[i].end(),winding,false);
Chris@16 691 }
Chris@16 692 }
Chris@16 693 prev_point = curr_prev;
Chris@16 694
Chris@16 695 } else {
Chris@16 696 treat_as_concave = true;
Chris@16 697 }
Chris@16 698 }
Chris@16 699
Chris@16 700 prev_concave = treat_as_concave;
Chris@16 701 first = second;
Chris@16 702 second = third;
Chris@16 703 ++third;
Chris@16 704 if(third == real_end) {
Chris@16 705 third = begin_points(poly);
Chris@16 706 if(*second == *third) {
Chris@16 707 ++third; //skip first point if it is duplicate of last point
Chris@16 708 }
Chris@16 709 }
Chris@16 710 } while(second != end);
Chris@16 711
Chris@16 712 // handle insertion of first point
Chris@16 713 if (!prev_concave) {
Chris@16 714 first_pts[first_pts.size()-1]=prev_point;
Chris@16 715 }
Chris@16 716 sizingSet.insert_vertex_sequence(first_pts.begin(),first_pts.end(),first_wdir,false);
Chris@16 717
Chris@16 718 polygon_set_data<coordinate_type> tmp;
Chris@16 719
Chris@16 720 //insert original shape
Chris@16 721 tmp.insert(poly, false, polygon_concept());
Chris@16 722 if((resizing < 0) ^ hole) tmp -= sizingSet;
Chris@16 723 else tmp += sizingSet;
Chris@16 724 //tmp.clean();
Chris@16 725 insert(tmp, hole);
Chris@16 726 return (*this);
Chris@16 727 }
Chris@16 728
Chris@16 729
Chris@16 730 inline polygon_set_data&
Chris@16 731 interact(const polygon_set_data& that);
Chris@16 732
Chris@16 733 inline bool downcast(polygon_45_set_data<coordinate_type>& result) const {
Chris@16 734 if(!is_45_) return false;
Chris@16 735 for(iterator_type itr = begin(); itr != end(); ++itr) {
Chris@16 736 const element_type& elem = *itr;
Chris@16 737 int count = elem.second;
Chris@16 738 int rise = 1; //up sloping 45
Chris@16 739 if(scanline_base<coordinate_type>::is_horizontal(elem.first)) rise = 0;
Chris@16 740 else if(scanline_base<coordinate_type>::is_vertical(elem.first)) rise = 2;
Chris@16 741 else {
Chris@16 742 if(!scanline_base<coordinate_type>::is_45_degree(elem.first)) {
Chris@16 743 is_45_ = false;
Chris@16 744 return false; //consider throwing because is_45_ has be be wrong
Chris@16 745 }
Chris@16 746 if(elem.first.first.y() > elem.first.second.y()) rise = -1; //down sloping 45
Chris@16 747 }
Chris@16 748 typename polygon_45_set_data<coordinate_type>::Vertex45Compact vertex(elem.first.first, rise, count);
Chris@16 749 result.insert(vertex);
Chris@16 750 typename polygon_45_set_data<coordinate_type>::Vertex45Compact vertex2(elem.first.second, rise, -count);
Chris@16 751 result.insert(vertex2);
Chris@16 752 }
Chris@16 753 return true;
Chris@16 754 }
Chris@16 755
Chris@16 756 inline GEOMETRY_CONCEPT_ID concept_downcast() const {
Chris@16 757 typedef typename coordinate_traits<coordinate_type>::coordinate_difference delta_type;
Chris@16 758 bool is_45 = false;
Chris@16 759 for(iterator_type itr = begin(); itr != end(); ++itr) {
Chris@16 760 const element_type& elem = *itr;
Chris@16 761 delta_type h_delta = euclidean_distance(elem.first.first, elem.first.second, HORIZONTAL);
Chris@16 762 delta_type v_delta = euclidean_distance(elem.first.first, elem.first.second, VERTICAL);
Chris@16 763 if(h_delta != 0 || v_delta != 0) {
Chris@16 764 //neither delta is zero and the edge is not MANHATTAN
Chris@16 765 if(v_delta != h_delta && v_delta != -h_delta) return POLYGON_SET_CONCEPT;
Chris@16 766 else is_45 = true;
Chris@16 767 }
Chris@16 768 }
Chris@16 769 if(is_45) return POLYGON_45_SET_CONCEPT;
Chris@16 770 return POLYGON_90_SET_CONCEPT;
Chris@16 771 }
Chris@16 772
Chris@16 773 private:
Chris@16 774 mutable value_type data_;
Chris@16 775 mutable bool dirty_;
Chris@16 776 mutable bool unsorted_;
Chris@16 777 mutable bool is_45_;
Chris@16 778
Chris@16 779 private:
Chris@16 780 //functions
Chris@16 781
Chris@16 782 template <typename output_container>
Chris@16 783 void get_dispatch(output_container& output, polygon_concept tag) const {
Chris@16 784 get_fracture(output, true, tag);
Chris@16 785 }
Chris@16 786 template <typename output_container>
Chris@16 787 void get_dispatch(output_container& output, polygon_with_holes_concept tag) const {
Chris@16 788 get_fracture(output, false, tag);
Chris@16 789 }
Chris@16 790 template <typename output_container, typename concept_type>
Chris@16 791 void get_fracture(output_container& container, bool fracture_holes, concept_type ) const {
Chris@16 792 clean();
Chris@16 793 polygon_arbitrary_formation<coordinate_type> pf(fracture_holes);
Chris@16 794 typedef typename polygon_arbitrary_formation<coordinate_type>::vertex_half_edge vertex_half_edge;
Chris@16 795 std::vector<vertex_half_edge> data;
Chris@16 796 for(iterator_type itr = data_.begin(); itr != data_.end(); ++itr){
Chris@16 797 data.push_back(vertex_half_edge((*itr).first.first, (*itr).first.second, (*itr).second));
Chris@16 798 data.push_back(vertex_half_edge((*itr).first.second, (*itr).first.first, -1 * (*itr).second));
Chris@16 799 }
Chris@16 800 polygon_sort(data.begin(), data.end());
Chris@16 801 pf.scan(container, data.begin(), data.end());
Chris@16 802 }
Chris@16 803 };
Chris@16 804
Chris@16 805 struct polygon_set_concept;
Chris@16 806 template <typename T>
Chris@16 807 struct geometry_concept<polygon_set_data<T> > {
Chris@16 808 typedef polygon_set_concept type;
Chris@16 809 };
Chris@16 810
Chris@16 811 // template <typename T>
Chris@16 812 // inline double compute_area(point_data<T>& a, point_data<T>& b, point_data<T>& c) {
Chris@16 813
Chris@16 814 // return (double)(b.x()-a.x())*(double)(c.y()-a.y())- (double)(c.x()-a.x())*(double)(b.y()-a.y());
Chris@16 815
Chris@16 816
Chris@16 817 // }
Chris@16 818
Chris@16 819 template <typename T>
Chris@16 820 inline int make_resizing_vertex_list(std::vector<std::vector<point_data< T> > >& return_points,
Chris@16 821 point_data<T>& curr_prev, bool ignore_prev_point,
Chris@16 822 point_data< T> start, point_data<T> middle, point_data< T> end,
Chris@16 823 double sizing_distance, unsigned int num_circle_segments, bool corner_fill_arc) {
Chris@16 824
Chris@16 825 // handle the case of adding an intersection point
Chris@16 826 point_data<double> dn1( middle.y()-start.y(), start.x()-middle.x());
Chris@16 827 double size = sizing_distance/std::sqrt( dn1.x()*dn1.x()+dn1.y()*dn1.y());
Chris@16 828 dn1 = point_data<double>( dn1.x()*size, dn1.y()* size);
Chris@16 829 point_data<double> dn2( end.y()-middle.y(), middle.x()-end.x());
Chris@16 830 size = sizing_distance/std::sqrt( dn2.x()*dn2.x()+dn2.y()*dn2.y());
Chris@16 831 dn2 = point_data<double>( dn2.x()*size, dn2.y()* size);
Chris@16 832 point_data<double> start_offset((start.x()+dn1.x()),(start.y()+dn1.y()));
Chris@16 833 point_data<double> mid1_offset((middle.x()+dn1.x()),(middle.y()+dn1.y()));
Chris@16 834 point_data<double> end_offset((end.x()+dn2.x()),(end.y()+dn2.y()));
Chris@16 835 point_data<double> mid2_offset((middle.x()+dn2.x()),(middle.y()+dn2.y()));
Chris@16 836 if (ignore_prev_point)
Chris@16 837 curr_prev = round_down<T>(start_offset);
Chris@16 838
Chris@16 839
Chris@16 840 if (corner_fill_arc) {
Chris@16 841 std::vector<point_data< T> > return_points1;
Chris@16 842 return_points.push_back(return_points1);
Chris@16 843 std::vector<point_data< T> >& return_points_back = return_points[return_points.size()-1];
Chris@16 844 return_points_back.push_back(round_down<T>(mid1_offset));
Chris@16 845 return_points_back.push_back(middle);
Chris@16 846 return_points_back.push_back(start);
Chris@16 847 return_points_back.push_back(curr_prev);
Chris@16 848 point_data<double> dmid(middle.x(),middle.y());
Chris@16 849 return_points.push_back(return_points1);
Chris@16 850 int num = make_arc(return_points[return_points.size()-1],mid1_offset,mid2_offset,dmid,sizing_distance,num_circle_segments);
Chris@16 851 curr_prev = round_down<T>(mid2_offset);
Chris@16 852 return num;
Chris@16 853
Chris@16 854 }
Chris@16 855
Chris@16 856 std::pair<point_data<double>,point_data<double> > he1(start_offset,mid1_offset);
Chris@16 857 std::pair<point_data<double>,point_data<double> > he2(mid2_offset ,end_offset);
Chris@16 858 //typedef typename high_precision_type<double>::type high_precision;
Chris@16 859
Chris@16 860 point_data<T> intersect;
Chris@16 861 typename scanline_base<T>::compute_intersection_pack pack;
Chris@16 862 bool res = pack.compute_intersection(intersect,he1,he2,true);
Chris@16 863 if( res ) {
Chris@16 864 std::vector<point_data< T> > return_points1;
Chris@16 865 return_points.push_back(return_points1);
Chris@16 866 std::vector<point_data< T> >& return_points_back = return_points[return_points.size()-1];
Chris@16 867 return_points_back.push_back(intersect);
Chris@16 868 return_points_back.push_back(middle);
Chris@16 869 return_points_back.push_back(start);
Chris@16 870 return_points_back.push_back(curr_prev);
Chris@16 871
Chris@16 872 //double d1= compute_area(intersect,middle,start);
Chris@16 873 //double d2= compute_area(start,curr_prev,intersect);
Chris@16 874
Chris@16 875 curr_prev = intersect;
Chris@16 876
Chris@16 877
Chris@16 878 return return_points.size();
Chris@16 879 }
Chris@16 880 return 0;
Chris@16 881
Chris@16 882 }
Chris@16 883
Chris@16 884 // this routine should take in start and end point s.t. end point is CCW from start
Chris@16 885 // it sould make a pie slice polygon that is an intersection of that arc
Chris@16 886 // with an ngon segments approximation of the circle centered at center with radius r
Chris@16 887 // point start is gauaranteed to be on the segmentation
Chris@16 888 // returnPoints will start with the first point after start
Chris@16 889 // returnPoints vector may be empty
Chris@16 890 template <typename T>
Chris@16 891 inline int make_arc(std::vector<point_data< T> >& return_points,
Chris@16 892 point_data< double> start, point_data< double> end,
Chris@16 893 point_data< double> center, double r, unsigned int num_circle_segments) {
Chris@16 894 const double our_pi=3.1415926535897932384626433832795028841971;
Chris@16 895
Chris@16 896 // derive start and end angles
Chris@16 897 double ps = atan2(start.y()-center.y(), start.x()-center.x());
Chris@16 898 double pe = atan2(end.y()-center.y(), end.x()-center.x());
Chris@16 899 if (ps < 0.0)
Chris@16 900 ps += 2.0 * our_pi;
Chris@16 901 if (pe <= 0.0)
Chris@16 902 pe += 2.0 * our_pi;
Chris@16 903 if (ps >= 2.0 * our_pi)
Chris@16 904 ps -= 2.0 * our_pi;
Chris@16 905 while (pe <= ps)
Chris@16 906 pe += 2.0 * our_pi;
Chris@16 907 double delta_angle = (2.0 * our_pi) / (double)num_circle_segments;
Chris@16 908 if ( start==end) // full circle?
Chris@16 909 {
Chris@16 910 ps = delta_angle*0.5;
Chris@16 911 pe = ps + our_pi * 2.0;
Chris@16 912 double x,y;
Chris@16 913 x = center.x() + r * cos(ps);
Chris@16 914 y = center.y() + r * sin(ps);
Chris@16 915 start = point_data<double>(x,y);
Chris@16 916 end = start;
Chris@16 917 }
Chris@16 918 return_points.push_back(round_down<T>(center));
Chris@16 919 return_points.push_back(round_down<T>(start));
Chris@16 920 unsigned int i=0;
Chris@16 921 double curr_angle = ps+delta_angle;
Chris@16 922 while( curr_angle < pe - 0.01 && i < 2 * num_circle_segments) {
Chris@16 923 i++;
Chris@16 924 double x = center.x() + r * cos( curr_angle);
Chris@16 925 double y = center.y() + r * sin( curr_angle);
Chris@16 926 return_points.push_back( round_down<T>((point_data<double>(x,y))));
Chris@16 927 curr_angle+=delta_angle;
Chris@16 928 }
Chris@16 929 return_points.push_back(round_down<T>(end));
Chris@16 930 return return_points.size();
Chris@16 931 }
Chris@16 932
Chris@16 933 }// close namespace
Chris@16 934 }// close name space
Chris@16 935
Chris@16 936 #include "detail/scan_arbitrary.hpp"
Chris@16 937
Chris@16 938 namespace boost { namespace polygon {
Chris@16 939 //ConnectivityExtraction computes the graph of connectivity between rectangle, polygon and
Chris@16 940 //polygon set graph nodes where an edge is created whenever the geometry in two nodes overlap
Chris@16 941 template <typename coordinate_type>
Chris@16 942 class connectivity_extraction{
Chris@16 943 private:
Chris@16 944 typedef arbitrary_connectivity_extraction<coordinate_type, int> ce;
Chris@16 945 ce ce_;
Chris@16 946 unsigned int nodeCount_;
Chris@16 947 public:
Chris@16 948 inline connectivity_extraction() : ce_(), nodeCount_(0) {}
Chris@16 949 inline connectivity_extraction(const connectivity_extraction& that) : ce_(that.ce_),
Chris@16 950 nodeCount_(that.nodeCount_) {}
Chris@16 951 inline connectivity_extraction& operator=(const connectivity_extraction& that) {
Chris@16 952 ce_ = that.ce_;
Chris@16 953 nodeCount_ = that.nodeCount_; {}
Chris@16 954 return *this;
Chris@16 955 }
Chris@16 956
Chris@16 957 //insert a polygon set graph node, the value returned is the id of the graph node
Chris@16 958 inline unsigned int insert(const polygon_set_data<coordinate_type>& ps) {
Chris@16 959 ps.clean();
Chris@16 960 ce_.populateTouchSetData(ps.begin(), ps.end(), nodeCount_);
Chris@16 961 return nodeCount_++;
Chris@16 962 }
Chris@16 963 template <class GeoObjT>
Chris@16 964 inline unsigned int insert(const GeoObjT& geoObj) {
Chris@16 965 polygon_set_data<coordinate_type> ps;
Chris@16 966 ps.insert(geoObj);
Chris@16 967 return insert(ps);
Chris@16 968 }
Chris@16 969
Chris@16 970 //extract connectivity and store the edges in the graph
Chris@16 971 //graph must be indexable by graph node id and the indexed value must be a std::set of
Chris@16 972 //graph node id
Chris@16 973 template <class GraphT>
Chris@16 974 inline void extract(GraphT& graph) {
Chris@16 975 ce_.execute(graph);
Chris@16 976 }
Chris@16 977 };
Chris@16 978
Chris@16 979 template <typename T>
Chris@16 980 polygon_set_data<T>&
Chris@16 981 polygon_set_data<T>::interact(const polygon_set_data<T>& that) {
Chris@16 982 connectivity_extraction<coordinate_type> ce;
Chris@16 983 std::vector<polygon_with_holes_data<T> > polys;
Chris@16 984 get(polys);
Chris@16 985 clear();
Chris@16 986 for(std::size_t i = 0; i < polys.size(); ++i) {
Chris@16 987 ce.insert(polys[i]);
Chris@16 988 }
Chris@16 989 int id = ce.insert(that);
Chris@16 990 std::vector<std::set<int> > graph(id+1);
Chris@16 991 ce.extract(graph);
Chris@16 992 for(std::set<int>::iterator itr = graph[id].begin();
Chris@16 993 itr != graph[id].end(); ++itr) {
Chris@16 994 insert(polys[*itr]);
Chris@16 995 }
Chris@16 996 return *this;
Chris@16 997 }
Chris@16 998 }
Chris@16 999 }
Chris@16 1000
Chris@16 1001 #include "polygon_set_traits.hpp"
Chris@16 1002 #include "detail/polygon_set_view.hpp"
Chris@16 1003
Chris@16 1004 #include "polygon_set_concept.hpp"
Chris@16 1005 #include "detail/minkowski.hpp"
Chris@16 1006 #endif