kicad/include/boost/polygon/gtl_boost_unit_test.cpp

3373 lines
126 KiB
C++

/*
Copyright 2008 Intel Corporation
Use, modification and distribution are subject to the Boost Software License,
Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at
http://www.boost.org/LICENSE_1_0.txt).
*/
#define BOOST_POLYGON_NO_DEPS
#include <iostream>
#define BOOST_VERY_LITTLE_SFINAE
//#include <boost/polygon/polygon.hpp>
#include "polygon.hpp"
//#include "ac_int_override.hpp"
namespace gtl = boost::polygon;
using namespace boost::polygon::operators;
#include <time.h>
#include <stdlib.h>
namespace boost { namespace polygon{
template <class T>
std::ostream& operator << (std::ostream& o, const interval_data<T>& i)
{
return o << i.get(LOW) << ' ' << i.get(HIGH);
}
template <class T>
std::ostream& operator << (std::ostream& o, const point_data<T>& r)
{
return o << r.get(HORIZONTAL) << ' ' << r.get(VERTICAL);
}
template <typename T>
std::ostream& operator<<(std::ostream& o, const polygon_45_data<T>& poly) {
o << "Polygon { ";
for(typename polygon_45_data<T>::iterator_type itr = poly.begin();
itr != poly.end(); ++itr) {
if(itr != poly.begin()) o << ", ";
o << (*itr).get(HORIZONTAL) << " " << (*itr).get(VERTICAL);
}
o << " } ";
return o;
}
template <typename Unit>
inline std::ostream& operator<< (std::ostream& o, const polygon_45_set_data<Unit>& p) {
o << "Polygon45Set ";
o << " " << !p.sorted() << " " << p.dirty() << " { ";
for(typename polygon_45_set_data<Unit>::iterator_type itr = p.begin();
itr != p.end(); ++itr) {
o << (*itr).pt << ":";
for(unsigned int i = 0; i < 4; ++i) {
o << (*itr).count[i] << ",";
} o << " ";
//o << (*itr).first << ":" << (*itr).second << "; ";
}
o << "} ";
return o;
}
template <typename Unit>
inline std::istream& operator>> (std::istream& i, polygon_45_set_data<Unit>& p) {
//TODO
return i;
}
template <typename T>
std::ostream& operator << (std::ostream& o, const polygon_90_data<T>& r)
{
o << "Polygon { ";
for(typename polygon_90_data<T>::iterator_type itr = r.begin(); itr != r.end(); ++itr) {
o << *itr << ", ";
}
return o << "} ";
}
template <typename T>
std::istream& operator >> (std::istream& i, polygon_90_data<T>& r)
{
std::size_t size;
i >> size;
std::vector<T> vec;
vec.reserve(size);
for(std::size_t ii = 0; ii < size; ++ii) {
T coord;
i >> coord;
vec.push_back(coord);
}
r.set_compact(vec.begin(), vec.end());
return i;
}
template <typename T>
std::ostream& operator << (std::ostream& o, const std::vector<polygon_90_data<T> >& r) {
o << r.size() << ' ';
for(std::size_t ii = 0; ii < r.size(); ++ii) {
o << (r[ii]);
}
return o;
}
template <typename T>
std::istream& operator >> (std::istream& i, std::vector<polygon_90_data<T> >& r) {
std::size_t size;
i >> size;
r.clear();
r.reserve(size);
for(std::size_t ii = 0; ii < size; ++ii) {
polygon_90_data<T> tmp;
i >> tmp;
r.push_back(tmp);
}
return i;
}
template <typename T>
std::ostream& operator<<(std::ostream& o, const polygon_data<T>& poly) {
o << "Polygon { ";
for(typename polygon_data<T>::iterator_type itr = poly.begin();
itr != poly.end(); ++itr) {
if(itr != poly.begin()) o << ", ";
o << (*itr).get(HORIZONTAL) << " " << (*itr).get(VERTICAL);
}
o << " } ";
return o;
}
template <typename T>
std::ostream& operator << (std::ostream& o, const polygon_set_data<T>& r)
{
o << "Polygon Set Data { ";
for(typename polygon_set_data<T>::iterator_type itr = r.begin(); itr != r.end(); ++itr) {
o << "<" << (*itr).first.first << ", " << (*itr).first.second << ">:" << (*itr).second << " ";
}
o << "} ";
return o;
}
template <typename T>
std::ostream& operator<<(std::ostream& o, const polygon_90_with_holes_data<T>& poly) {
o << "Polygon With Holes { ";
for(typename polygon_90_with_holes_data<T>::iterator_type itr = poly.begin();
itr != poly.end(); ++itr) {
if(itr != poly.begin()) o << ", ";
o << (*itr).get(HORIZONTAL) << " " << (*itr).get(VERTICAL);
} o << " { ";
for(typename polygon_90_with_holes_data<T>::iterator_holes_type itr = poly.begin_holes();
itr != poly.end_holes(); ++itr) {
o << (*itr);
}
o << " } } ";
return o;
}
template <typename T>
std::ostream& operator<<(std::ostream& o, const polygon_45_with_holes_data<T>& poly) {
o << "Polygon With Holes { ";
for(typename polygon_45_with_holes_data<T>::iterator_type itr = poly.begin();
itr != poly.end(); ++itr) {
if(itr != poly.begin()) o << ", ";
o << (*itr).get(HORIZONTAL) << " " << (*itr).get(VERTICAL);
} o << " { ";
for(typename polygon_45_with_holes_data<T>::iterator_holes_type itr = poly.begin_holes();
itr != poly.end_holes(); ++itr) {
o << (*itr);
}
o << " } } ";
return o;
}
template <typename T>
std::ostream& operator<<(std::ostream& o, const polygon_with_holes_data<T>& poly) {
o << "Polygon With Holes { ";
for(typename polygon_with_holes_data<T>::iterator_type itr = poly.begin();
itr != poly.end(); ++itr) {
if(itr != poly.begin()) o << ", ";
o << (*itr).get(HORIZONTAL) << " " << (*itr).get(VERTICAL);
} o << " { ";
for(typename polygon_with_holes_data<T>::iterator_holes_type itr = poly.begin_holes();
itr != poly.end_holes(); ++itr) {
o << (*itr);
}
o << " } } ";
return o;
}
template <class T>
std::ostream& operator << (std::ostream& o, const rectangle_data<T>& r)
{
return o << r.get(HORIZONTAL) << ' ' << r.get(VERTICAL);
}
template <typename T>
typename enable_if<typename is_polygon_90_set_type<T>::type, void>::type
print_is_polygon_90_set_concept(const T& ) { std::cout << "is polygon 90 set concept\n"; }
template <typename T>
typename enable_if<typename is_mutable_polygon_90_set_type<T>::type, void>::type
print_is_mutable_polygon_90_set_concept(const T& ) { std::cout << "is mutable polygon 90 set concept\n"; }
namespace boolean_op {
//self contained unit test for BooleanOr algorithm
template <typename Unit>
inline bool testBooleanOr() {
BooleanOp<int, Unit> booleanOr;
//test one rectangle
std::vector<std::pair<interval_data<Unit>, int> > container;
booleanOr.processInterval(container, interval_data<Unit>(0, 10), 1);
booleanOr.advanceScan();
booleanOr.processInterval(container, interval_data<Unit>(0, 10), -1);
if(container.size() != 2) {
std::cout << "Test one rectangle, wrong output size\n";
return false;
}
if(container[0] != std::pair<interval_data<Unit>, int>(interval_data<Unit>(0, 10), 1)) {
std::cout << "Test one rectangle, first output wrong: Interval(" <<
container[0].first << "), " << container[0].second << std::endl;
}
if(container[1] != std::pair<interval_data<Unit>, int>(interval_data<Unit>(0, 10), -1)) {
std::cout << "Test one rectangle, second output wrong: Interval(" <<
container[1].first << "), " << container[1].second << std::endl;
}
//test two rectangles
container.clear();
booleanOr = BooleanOp<int, Unit>();
booleanOr.processInterval(container, interval_data<Unit>(0, 10), 1);
booleanOr.advanceScan();
booleanOr.processInterval(container, interval_data<Unit>(5, 15), 1);
booleanOr.advanceScan();
booleanOr.processInterval(container, interval_data<Unit>(0, 10), -1);
booleanOr.advanceScan();
booleanOr.processInterval(container, interval_data<Unit>(5, 15), -1);
if(container.size() != 4) {
std::cout << "Test two rectangles, wrong output size\n";
for(std::size_t i = 0; i < container.size(); ++i){
std::cout << container[i].first << "), " << container[i].second << std::endl;
}
return false;
}
if(container[0] != std::pair<interval_data<Unit>, int>(interval_data<Unit>(0, 10), 1)) {
std::cout << "Test two rectangles, first output wrong: Interval(" <<
container[0].first << "), " << container[0].second << std::endl;
}
if(container[1] != std::pair<interval_data<Unit>, int>(interval_data<Unit>(10, 15), 1)) {
std::cout << "Test two rectangles, second output wrong: Interval(" <<
container[1].first << "), " << container[1].second << std::endl;
}
if(container[2] != std::pair<interval_data<Unit>, int>(interval_data<Unit>(0, 5), -1)) {
std::cout << "Test two rectangles, third output wrong: Interval(" <<
container[2].first << "), " << container[2].second << std::endl;
}
if(container[3] != std::pair<interval_data<Unit>, int>(interval_data<Unit>(5, 15), -1)) {
std::cout << "Test two rectangles, fourth output wrong: Interval(" <<
container[3].first << "), " << container[3].second << std::endl;
}
//test two rectangles
container.clear();
booleanOr = BooleanOp<int, Unit>();
booleanOr.processInterval(container, interval_data<Unit>(5, 15), 1);
booleanOr.advanceScan();
booleanOr.processInterval(container, interval_data<Unit>(0, 10), 1);
booleanOr.advanceScan();
booleanOr.processInterval(container, interval_data<Unit>(5, 15), -1);
booleanOr.advanceScan();
booleanOr.processInterval(container, interval_data<Unit>(0, 10), -1);
if(container.size() != 4) {
std::cout << "Test other two rectangles, wrong output size\n";
for(std::size_t i = 0; i < container.size(); ++i){
std::cout << container[i].first << "), " << container[i].second << std::endl;
}
return false;
}
if(container[0] != std::pair<interval_data<Unit>, int>(interval_data<Unit>(5, 15), 1)) {
std::cout << "Test other two rectangles, first output wrong: Interval(" <<
container[0].first << "), " << container[0].second << std::endl;
}
if(container[1] != std::pair<interval_data<Unit>, int>(interval_data<Unit>(0, 5), 1)) {
std::cout << "Test other two rectangles, second output wrong: Interval(" <<
container[1].first << "), " << container[1].second << std::endl;
}
if(container[2] != std::pair<interval_data<Unit>, int>(interval_data<Unit>(10, 15), -1)) {
std::cout << "Test other two rectangles, third output wrong: Interval(" <<
container[2].first << "), " << container[2].second << std::endl;
}
if(container[3] != std::pair<interval_data<Unit>, int>(interval_data<Unit>(0, 10), -1)) {
std::cout << "Test other two rectangles, fourth output wrong: Interval(" <<
container[3].first << "), " << container[3].second << std::endl;
}
//test two nonoverlapping rectangles
container.clear();
booleanOr = BooleanOp<int, Unit>();
booleanOr.processInterval(container, interval_data<Unit>(0, 10), 1);
booleanOr.advanceScan();
booleanOr.processInterval(container, interval_data<Unit>(15, 25), 1);
booleanOr.advanceScan();
booleanOr.processInterval(container, interval_data<Unit>(0, 10), -1);
booleanOr.advanceScan();
booleanOr.processInterval(container, interval_data<Unit>(15, 25), -1);
if(container.size() != 4) {
std::cout << "Test two nonoverlapping rectangles, wrong output size\n";
return false;
}
if(container[0] != std::pair<interval_data<Unit>, int>(interval_data<Unit>(0, 10), 1)) {
std::cout << "Test two nonoverlapping rectangles, first output wrong: Interval(" <<
container[0].first << "), " << container[0].second << std::endl;
}
if(container[1] != std::pair<interval_data<Unit>, int>(interval_data<Unit>(15, 25), 1)) {
std::cout << "Test two nonoverlapping rectangles, second output wrong: Interval(" <<
container[1].first << "), " << container[1].second << std::endl;
}
if(container[2] != std::pair<interval_data<Unit>, int>(interval_data<Unit>(0, 10), -1)) {
std::cout << "Test two nonoverlapping rectangles, third output wrong: Interval(" <<
container[2].first << "), " << container[2].second << std::endl;
}
if(container[3] != std::pair<interval_data<Unit>, int>(interval_data<Unit>(15, 25), -1)) {
std::cout << "Test two nonoverlapping rectangles, fourth output wrong: Interval(" <<
container[3].first << "), " << container[3].second << std::endl;
}
return true;
}
}
void test_assign() {
using namespace gtl;
std::vector<polygon_data<int> > ps;
polygon_90_set_data<int> ps90;
assign(ps, ps90);
}
//this is a compile time test, if it compiles it passes
void test_view_as() {
using namespace gtl;
polygon_data<int> p;
polygon_45_data<int> p45;
polygon_90_data<int> p90;
polygon_with_holes_data<int> pwh;
polygon_45_with_holes_data<int> p45wh;
polygon_90_with_holes_data<int> p90wh;
rectangle_data<int> rect(0, 1, 10, 11);
polygon_90_set_data<int> ps90;
polygon_45_set_data<int> ps45;
polygon_set_data<int> ps;
assign(p, rect);
assign(p90, view_as<polygon_90_concept>(p));
if(!equivalence(p90, rect))
std::cout << "fail 1\n";
assign(p45, view_as<polygon_45_concept>(p));
if(!equivalence(p45, rect))
std::cout << "fail 2\n";
assign(p90, view_as<polygon_90_concept>(p45));
if(!equivalence(p90, rect))
std::cout << "fail 3\n";
if(!equivalence(rect, view_as<rectangle_concept>(p)))
std::cout << "fail 4\n";
if(!equivalence(rect, view_as<rectangle_concept>(p45)))
std::cout << "fail 5\n";
if(!equivalence(rect, view_as<rectangle_concept>(p90)))
std::cout << "fail 6\n";
assign(pwh, rect);
assign(p90wh, rect);
assign(p45wh, rect);
if(!equivalence(rect, view_as<rectangle_concept>(pwh)))
std::cout << "fail 7\n";
if(!equivalence(rect, view_as<rectangle_concept>(p45wh)))
std::cout << "fail 8\n";
if(!equivalence(rect, view_as<rectangle_concept>(p90wh)))
std::cout << "fail 9\n";
assign(p90wh, view_as<polygon_90_with_holes_concept>(pwh));
if(!equivalence(p90wh, rect))
std::cout << "fail 10\n";
assign(p45wh, view_as<polygon_45_with_holes_concept>(pwh));
if(!equivalence(p45wh, rect))
std::cout << "fail 11\n";
assign(p90wh, view_as<polygon_90_with_holes_concept>(p45wh));
if(!equivalence(p90wh, rect))
std::cout << "fail 12\n";
assign(p90, view_as<polygon_90_concept>(pwh));
if(!equivalence(p90, rect))
std::cout << "fail 13\n";
assign(p45, view_as<polygon_45_concept>(pwh));
if(!equivalence(p45, rect))
std::cout << "fail 14\n";
assign(p90, view_as<polygon_90_concept>(p45wh));
if(!equivalence(p90, rect))
std::cout << "fail 15\n";
assign(ps, rect);
assign(ps90, view_as<polygon_90_set_concept>(ps));
if(!equivalence(ps90, rect))
std::cout << "fail 16\n";
assign(ps45, view_as<polygon_45_set_concept>(ps));
if(!equivalence(ps45, rect))
std::cout << "fail 17\n";
assign(ps90, view_as<polygon_90_set_concept>(ps45));
if(!equivalence(ps90, rect))
std::cout << "fail 18\n";
}
inline bool testPolygon45SetRect() {
std::vector<point_data<int> > points;
points.push_back(point_data<int>(0,0));
points.push_back(point_data<int>(0,10));
points.push_back(point_data<int>(10,10));
points.push_back(point_data<int>(10,0));
polygon_45_data<int> poly;
poly.set(points.begin(), points.end());
polygon_45_set_data<int> ps;
ps.insert(poly);
std::vector<polygon_45_data<int> > polys;
ps.get_polygons(polys);
std::cout << polys.size() << std::endl;
for(unsigned int i = 0; i < polys.size(); ++i) {
std::cout << polys[i] << std::endl;
}
return true;
}
inline bool testPolygon45Set() {
polygon_45_formation<int>::Polygon45Formation pf(true);
typedef boolean_op_45<int>::Vertex45 Vertex45;
std::vector<Vertex45> data;
// result == 0 8 -1 1
data.push_back(Vertex45(point_data<int>(0, 8), -1, 1));
// result == 0 8 1 -1
data.push_back(Vertex45(point_data<int>(0, 8), 1, -1));
// result == 4 0 1 1
data.push_back(Vertex45(point_data<int>(4, 0), 1, 1));
// result == 4 0 2 1
data.push_back(Vertex45(point_data<int>(4, 0), 2, 1));
// result == 4 4 2 -1
data.push_back(Vertex45(point_data<int>(4, 4), 2, -1));
// result == 4 4 -1 -1
data.push_back(Vertex45(point_data<int>(4, 4), -1, -1));
// result == 4 12 1 1
data.push_back(Vertex45(point_data<int>(4, 12), 1, 1));
// result == 4 12 2 1
data.push_back(Vertex45(point_data<int>(4, 12), 2, 1));
// result == 4 16 2 -1
data.push_back(Vertex45(point_data<int>(4, 16), 2, 1));
// result == 4 16 -1 -1
data.push_back(Vertex45(point_data<int>(4, 16), -1, -1));
// result == 6 2 1 -1
data.push_back(Vertex45(point_data<int>(6, 2), 1, -1));
// result == 6 14 -1 1
data.push_back(Vertex45(point_data<int>(6, 14), -1, 1));
// result == 6 2 -1 1
data.push_back(Vertex45(point_data<int>(6, 2), -1, 1));
// result == 6 14 1 -1
data.push_back(Vertex45(point_data<int>(6, 14), 1, -1));
// result == 8 0 -1 -1
data.push_back(Vertex45(point_data<int>(8, 0), -1, -1));
// result == 8 0 2 -1
data.push_back(Vertex45(point_data<int>(8, 0), 2, -1));
// result == 8 4 2 1
data.push_back(Vertex45(point_data<int>(8, 4), 2, 1));
// result == 8 4 1 1
data.push_back(Vertex45(point_data<int>(8, 4), 1, 1));
// result == 8 12 -1 -1
data.push_back(Vertex45(point_data<int>(8, 12), -1, -1));
// result == 8 12 2 -1
data.push_back(Vertex45(point_data<int>(8, 12), 2, -1));
// result == 8 16 2 1
data.push_back(Vertex45(point_data<int>(8, 16), 2, 1));
// result == 8 16 1 1
data.push_back(Vertex45(point_data<int>(8, 16), 1, 1));
// result == 12 8 1 -1
data.push_back(Vertex45(point_data<int>(12, 8), 1, -1));
// result == 12 8 -1 1
data.push_back(Vertex45(point_data<int>(12, 8), -1, 1));
data.push_back(Vertex45(point_data<int>(6, 4), 1, -1));
data.push_back(Vertex45(point_data<int>(6, 4), 2, -1));
data.push_back(Vertex45(point_data<int>(6, 12), -1, 1));
data.push_back(Vertex45(point_data<int>(6, 12), 2, 1));
data.push_back(Vertex45(point_data<int>(10, 8), -1, -1));
data.push_back(Vertex45(point_data<int>(10, 8), 1, 1));
std::sort(data.begin(), data.end());
std::vector<polygon_45_data<int> > polys;
pf.scan(polys, data.begin(), data.end());
polygon_45_set_data<int> ps;
std::cout << "inserting1\n";
//std::vector<point_data<int> > points;
//points.push_back(point_data<int>(0,0));
//points.push_back(point_data<int>(0,10));
//points.push_back(point_data<int>(10,10));
//points.push_back(point_data<int>(10,0));
//Polygon45 poly;
//poly.set(points.begin(), points.end());
//ps.insert(poly);
ps.insert(polys[0]);
polygon_45_set_data<int> ps2;
std::cout << "inserting2\n";
ps2.insert(polys[0]);
std::cout << "applying boolean\n";
ps |= ps2;
std::vector<polygon_45_data<int> > polys2;
std::cout << "getting result\n";
ps.get_polygons(polys2);
std::cout << ps2 << std::endl;
std::cout << ps << std::endl;
std::cout << polys[0] << std::endl;
std::cout << polys2[0] << std::endl;
if(polys != polys2) std::cout << "test Polygon45Set failed\n";
return polys == polys2;
}
inline bool testPolygon45SetPerterbation() {
polygon_45_formation<int>::Polygon45Formation pf(true);
typedef boolean_op_45<int>::Vertex45 Vertex45;
std::vector<Vertex45> data;
// result == 0 8 -1 1
data.push_back(Vertex45(point_data<int>(0, 80), -1, 1));
// result == 0 8 1 -1
data.push_back(Vertex45(point_data<int>(0, 80), 1, -1));
// result == 4 0 1 1
data.push_back(Vertex45(point_data<int>(40, 0), 1, 1));
// result == 4 0 2 1
data.push_back(Vertex45(point_data<int>(40, 0), 2, 1));
// result == 4 4 2 -1
data.push_back(Vertex45(point_data<int>(40, 40), 2, -1));
// result == 4 4 -1 -1
data.push_back(Vertex45(point_data<int>(40, 40), -1, -1));
// result == 4 12 1 1
data.push_back(Vertex45(point_data<int>(40, 120), 1, 1));
// result == 4 12 2 1
data.push_back(Vertex45(point_data<int>(40, 120), 2, 1));
// result == 4 16 2 -1
data.push_back(Vertex45(point_data<int>(40, 160), 2, 1));
// result == 4 16 -1 -1
data.push_back(Vertex45(point_data<int>(40, 160), -1, -1));
// result == 6 2 1 -1
data.push_back(Vertex45(point_data<int>(60, 20), 1, -1));
// result == 6 14 -1 1
data.push_back(Vertex45(point_data<int>(60, 140), -1, 1));
// result == 6 2 -1 1
data.push_back(Vertex45(point_data<int>(60, 20), -1, 1));
// result == 6 14 1 -1
data.push_back(Vertex45(point_data<int>(60, 140), 1, -1));
// result == 8 0 -1 -1
data.push_back(Vertex45(point_data<int>(80, 0), -1, -1));
// result == 8 0 2 -1
data.push_back(Vertex45(point_data<int>(80, 0), 2, -1));
// result == 8 4 2 1
data.push_back(Vertex45(point_data<int>(80, 40), 2, 1));
// result == 8 4 1 1
data.push_back(Vertex45(point_data<int>(80, 40), 1, 1));
// result == 8 12 -1 -1
data.push_back(Vertex45(point_data<int>(80, 120), -1, -1));
// result == 8 12 2 -1
data.push_back(Vertex45(point_data<int>(80, 120), 2, -1));
// result == 8 16 2 1
data.push_back(Vertex45(point_data<int>(80, 160), 2, 1));
// result == 8 16 1 1
data.push_back(Vertex45(point_data<int>(80, 160), 1, 1));
// result == 12 8 1 -1
data.push_back(Vertex45(point_data<int>(120, 80), 1, -1));
// result == 12 8 -1 1
data.push_back(Vertex45(point_data<int>(120, 80), -1, 1));
data.push_back(Vertex45(point_data<int>(60, 40), 1, -1));
data.push_back(Vertex45(point_data<int>(60, 40), 2, -1));
data.push_back(Vertex45(point_data<int>(60, 120), -1, 1));
data.push_back(Vertex45(point_data<int>(60, 120), 2, 1));
data.push_back(Vertex45(point_data<int>(100, 80), -1, -1));
data.push_back(Vertex45(point_data<int>(100, 80), 1, 1));
std::sort(data.begin(), data.end());
std::vector<polygon_45_data<int> > polys;
pf.scan(polys, data.begin(), data.end());
polygon_45_set_data<int> ps;
std::cout << "inserting1\n";
//std::vector<point_data<int> > points;
//points.push_back(point_data<int>(0,0));
//points.push_back(point_data<int>(0,10));
//points.push_back(point_data<int>(10,10));
//points.push_back(point_data<int>(10,0));
//Polygon45 poly;
//poly.set(points.begin(), points.end());
//ps.insert(poly);
polygon_45_set_data<int> preps(polys[0]);
ps.insert(polys[0]);
convolve(polys[0], point_data<int>(0, 1) );
polygon_45_set_data<int> ps2;
std::cout << "inserting2\n";
ps2.insert(polys[0]);
std::cout << "applying boolean\n";
ps |= ps2;
std::vector<polygon_45_data<int> > polys2;
std::cout << "getting result\n";
ps.get_polygons(polys2);
std::cout << preps << std::endl;
std::cout << ps2 << std::endl;
std::cout << ps << std::endl;
std::cout << polys[0] << std::endl;
std::cout << polys2[0] << std::endl;
if(polys != polys2) std::cout << "test Polygon45Set failed\n";
return polys == polys2;
//return true;
}
inline int testPolygon45SetDORA() {
std::cout << "testPolygon45SetDORA" << std::endl;
std::vector<point_data<int> > pts;
pts.push_back(point_data<int>(0, 0));
pts.push_back(point_data<int>(10, 0));
pts.push_back(point_data<int>(10, 10));
pts.push_back(point_data<int>(0, 10));
polygon_45_data<int> apoly;
apoly.set(pts.begin(), pts.end());
polygon_45_set_data<int> ps(apoly);
polygon_45_set_data<int> ps2(ps);
ps2 = apoly;
std::vector<polygon_45_data<int> > apolys;
apolys.push_back(apoly);
ps2.insert(apolys.begin(), apolys.end());
apolys.clear();
ps2.get(apolys);
std::cout << apolys.size() << std::endl;
std::cout << (ps == ps2) << std::endl;
std::cout << !(ps != ps2) << std::endl;
ps2.clear();
std::cout << (ps2.value().empty()) << std::endl;
ps2.set(apolys.begin(), apolys.end());
ps2.set(ps.value());
ps.clean();
ps2.set_clean(ps.value());
ps2.insert(ps.value().begin(), ps.value().end());
ps2.clear();
for(polygon_45_set_data<int>::iterator_type itr = ps.begin();
itr != ps.end(); ++itr) {
ps2.insert(*itr);
}
std::vector<polygon_45_with_holes_data<int> > apolywhs;
ps2.get_polygons_with_holes(apolywhs);
std::cout << apolywhs.size() << std::endl;
ps2 += 1;
apolywhs.clear();
ps2.get_polygons_with_holes(apolywhs);
if(apolywhs.size()) std::cout << apolywhs[0] << std::endl;
ps2 -= 1;
apolywhs.clear();
ps2.get_polygons_with_holes(apolywhs);
if(apolywhs.size()) std::cout << apolywhs[0] << std::endl;
else {
std::cout << "test failed\n";
return 1;
}
rectangle_data<int> rect;
extents(rect, apolywhs[0]);
ps2.clear();
ps2.insert(rect);
ps2.extents(rect);
ps2.clear();
ps2.insert(rect);
ps2.clear();
ps2.insert(apolywhs[0]);
apolywhs.clear();
ps2.get_trapezoids(apolywhs);
if(apolywhs.size()) std::cout << apolywhs[0] << std::endl;
else {
std::cout << "test failed\n";
return 1;
}
ps2 *= ps;
std::cout << (ps2 == ps) << std::endl;
ps2 ^= ps;
std::cout << ps2.empty() << std::endl;
axis_transformation atr(axis_transformation::WS);
ps2 = ps;
ps.transform(atr);
transformation<int> tr(atr);
tr.invert();
ps.transform(tr);
ps.scale_up(2);
ps.scale_down(2);
std::cout << (ps2 == ps) << std::endl;
pts.clear();
pts.push_back(point_data<int>(0,0));
pts.push_back(point_data<int>(10,10));
pts.push_back(point_data<int>(10,11));
pts.push_back(point_data<int>(0,21));
apoly.set(pts.begin(), pts.end());
ps2.clear();
ps2.insert(apoly);
ps2 -= 1;
apolywhs.clear();
ps2.get_polygons_with_holes(apolywhs);
if(apolywhs.size()) std::cout << apolywhs[0] << std::endl;
else {
std::cout << "test failed\n";
return 1;
}
pts.clear();
pts.push_back(point_data<int>(0, 0));
pts.push_back(point_data<int>(10, 10));
pts.push_back(point_data<int>(0, 20));
apoly.set(pts.begin(), pts.end());
ps2.clear();
ps2.insert(apoly);
pts.clear();
pts.push_back(point_data<int>(0, 5));
pts.push_back(point_data<int>(10, 15));
pts.push_back(point_data<int>(0, 25));
apoly.set(pts.begin(), pts.end());
ps2.insert(apoly);
apolywhs.clear();
ps2.get_polygons_with_holes(apolywhs);
if(apolywhs.size()) std::cout << apolywhs[0] << std::endl;
else {
std::cout << "test failed\n";
return 1;
}
return 0;
}
}
}
using namespace gtl;
bool testInterval() {
interval_data<int> interval(0, 10), interval2(10, 20);
if(!abuts(interval, interval2)) return false;
if(!boundaries_intersect(interval, interval2)) return false;
if(boundaries_intersect(interval, interval2, false)) return false;
if(intersect(interval, interval2, false)) return false;
if(!intersect(interval, interval2)) return false;
if(euclidean_distance(interval, interval2) != 0) return false;
encompass(interval, interval2);
set(interval, LOW, 0);
high(interval, 10);
scale(interval, 2.0f);
scale(interval, 0.5f);
if(low(interval) != 0) return false;
if(high(interval) != 10) return false;
move(interval, 10);
if(!equivalence(interval, interval2)) return false;
flip(interval, 10);
bloat(interval, -2);
shrink(interval, -2);
flip(interval, 10);
if(!equivalence(interval, interval2)) return false;
interval_data<int> half = get_half(interval, LOW);
if(high(half) != 15) return false;
convolve(interval, interval2);
if(high(interval) != 40) return false;
deconvolve(interval, interval2);
if(!equivalence(interval, interval2)) return false;
reflected_convolve(interval, interval2);
if(low(interval) != -10) return false;
reflected_deconvolve(interval, interval2);
if(!equivalence(interval, interval2)) return false;
euclidean_distance(interval, 0);
move(interval, 20);
if(euclidean_distance(interval, interval2) != 10) return false;
interval = interval2;
move(interval, -5);
if(!intersects(interval, interval2)) return false;
move(interval, 15);
if(!abuts(interval, interval2)) return false;
if(abuts(interval, interval2, HIGH)) return false;
move(interval, 10);
generalized_intersect(interval, interval2);
move(interval, -10);
if(!equivalence(interval, interval2)) return false;
if(get(interval, LOW) != low(interval)) return false;
if(get(interval, HIGH) != high(interval)) return false;
if(center(interval2) != 15) return false;
if(delta(interval2) != 10) return false;
assign(interval, interval2);
low(interval, 0);
if(low(interval) != 0) return false;
high(interval, 10);
join_with(interval, interval2);
if(high(interval) != high(interval2)) return false;
return true;
}
bool testRectangle() {
rectangle_data<int> rect, rect2;
#ifdef BOOST_POLYGON_MSVC
horizontal(rect, interval_data<int>(0, 10));
vertical(rect, interval_data<int>(20, 30));
#else
horizontal(rect, interval_data<long long>(0, 10));
vertical(rect, interval_data<long long>(20, 30));
#endif
xl(rect2, 0);
xh(rect2, 10);
yl(rect2, 20);
yh(rect2, 30);
if(euclidean_distance(rect, rect2) != 0) return false;
if(euclidean_distance(rect2, rect) != 0) return false;
#ifdef BOOST_POLYGON_MSVC
set(rect, HORIZONTAL, interval_data<int>(0, 10));
if(!equivalence(horizontal(rect), interval_data<int>(0, 10))) return false;
if(!equivalence(vertical(rect2), interval_data<int>(20, 30))) return false;
#else
set(rect, HORIZONTAL, interval_data<long long>(0, 10));
if(!equivalence(horizontal(rect), interval_data<long long>(0, 10))) return false;
if(!equivalence(vertical(rect2), interval_data<long long>(20, 30))) return false;
#endif
if(xl(rect) != 0) return false;
if(xh(rect) != 10) return false;
if(yl(rect) != 20) return false;
if(yh(rect) != 30) return false;
move(rect, HORIZONTAL, 10);
if(xl(rect) != 10) return false;
#ifdef BOOST_POLYGON_MSVC
set_points(rect, point_data<int>(0, 20), point_data<int>(10, 30));
#else
set_points(rect, point_data<int>(0, 20), point_data<long long>(10, 30));
#endif
if(xl(rect) != 0) return false;
convolve(rect, rect2);
if(xh(rect) != 20) return false;
deconvolve(rect, rect2);
if(xh(rect) != 10) return false;
reflected_convolve(rect, rect2);
reflected_deconvolve(rect, rect2);
if(!equivalence(rect, rect2)) return false;
#ifdef BOOST_POLYGON_MSVC
convolve(rect, point_data<int>(100, 200));
#else
convolve(rect, point_data<long long>(100, 200));
#endif
if(xh(rect) != 110) return false;
deconvolve(rect, point_data<int>(100, 200));
if(!equivalence(rect, rect2)) return false;
xh(rect, 100);
if(delta(rect, HORIZONTAL) != 100) return false;
if(area(rect) != 1000) return false;
if(half_perimeter(rect) != 110) return false;
if(perimeter(rect) != 220) return false;
if(guess_orientation(rect) != HORIZONTAL) return false;
return true;
}
bool testPolygon() {
int rect[4] = {0, 10, 20, 30};
iterator_compact_to_points<int*, point_data<int> > itr(rect, rect+4);
iterator_compact_to_points<int*, point_data<int> > itr_end(rect, rect+4);
std::vector<point_data<int> > points;
points.insert(points.end(), itr, itr_end);
polygon_90_data<int> p90;
assign(p90, rectangle_data<int>(interval_data<int>(0, 10), interval_data<int>(20, 30)));
if(winding(p90) != COUNTERCLOCKWISE) return false;
polygon_45_data<int> p45;
assign(p45, rectangle_data<int>(interval_data<int>(0, 10), interval_data<int>(20, 30)));
if(winding(p45) != COUNTERCLOCKWISE) return false;
polygon_data<int> p;
assign(p, rectangle_data<int>(interval_data<int>(0, 10), interval_data<int>(20, 30)));
if(winding(p) != COUNTERCLOCKWISE) return false;
set_compact(p90, rect, rect+4);
if(winding(p90) != COUNTERCLOCKWISE) return false;
points.clear();
points.push_back(point_data<int>(0, 0));
points.push_back(point_data<int>(10, 10));
points.push_back(point_data<int>(0, 20));
points.push_back(point_data<int>(-10, 10));
set_points(p45, points.begin(), points.end());
if(winding(p45) != COUNTERCLOCKWISE) return false;
std::swap(points[1], points[3]);
set_points(p, points.begin(), points.end());
if(winding(p) == COUNTERCLOCKWISE) return false;
point_data<int> cp;
center(cp, p);
if(cp != point_data<int>(0, 10)) return false;
move(p, HORIZONTAL, 3);
rectangle_data<int> bounding_box;
extents(bounding_box, p);
if(bounding_box != rectangle_data<int>(interval_data<int>(-7, 13), interval_data<int>(0, 20))) return false;
if(area(p90) != 400) return false;
if(area(p45) != 200) return false;
if(perimeter(p90) != 80) return false;
return true;
}
bool testPolygonAssign() {
polygon_data<int> p;
polygon_data<int> p1;
polygon_45_data<int> p_45;
polygon_45_data<int> p_451;
polygon_90_data<int> p_90;
polygon_90_data<int> p_901;
polygon_with_holes_data<int> p_wh;
polygon_with_holes_data<int> p_wh1;
polygon_45_with_holes_data<int> p_45_wh;
polygon_45_with_holes_data<int> p_45_wh1;
polygon_90_with_holes_data<int> p_90_wh;
polygon_90_with_holes_data<int> p_90_wh1;
assign(p, p1);
assign(p, p_45);
assign(p, p_90);
//assign(p, p_wh);
//assign(p, p_45_wh);
//assign(p, p_90_wh);
//assign(p_45, p);
assign(p_451, p_45);
assign(p_45, p_90);
//assign(p_45, p_wh);
//assign(p_45, p_45_wh);
//assign(p_45, p_90_wh);
//assign(p_90, p);
//assign(p_90, p_45);
assign(p_901, p_90);
//assign(p_90, p_wh);
//assign(p_90, p_45_wh);
//assign(p_90, p_90_wh);
assign(p_wh, p);
assign(p_wh, p_45);
assign(p_wh, p_90);
assign(p_wh1, p_wh);
assign(p_wh, p_45_wh);
assign(p_wh, p_90_wh);
//assign(p_45_wh, p);
assign(p_45_wh, p_45);
assign(p_45_wh, p_90);
//assign(p_45_wh, p_wh);
assign(p_45_wh1, p_45_wh);
//assign(p_90_wh, p);
//assign(p_90_wh, p_45);
assign(p_90_wh, p_90);
assign(p_90_wh1, p_90_wh);
return true;
}
int testPropertyMerge() {
rectangle_data<int> rect1 = construct<rectangle_data<int> >(0, 1, 10, 11);
rectangle_data<int> rect2 = construct<rectangle_data<int> >(5, 6, 17, 18);
property_merge_90<int, int> pm;
pm.insert(rect1, 0);
pm.insert(rect2, 1);
std::map<std::set<int>, polygon_90_set_data<int> > result;
pm.merge(result);
std::vector<rectangle_data<int> > rects;
std::set<int> key;
key.insert(0);
result[key].get(rects);
std::cout << rects.size() << std::endl;
std::vector<polygon_data<int> > polys;
result[key].get(polys);
std::cout << polys.size() << std::endl;
std::vector<polygon_90_with_holes_data<int> > polywhs;
result[key].get(polywhs);
std::cout << polys.size() << std::endl;
return result.size();
}
bool testPolygonWithHoles() {
int rect[4] = {0, 10, 20, 30};
iterator_compact_to_points<int*, point_data<int> > itr(rect, rect+4);
iterator_compact_to_points<int*, point_data<int> > itr_end(rect, rect+4);
std::vector<point_data<int> > points;
points.insert(points.end(), itr, itr_end);
polygon_45_with_holes_data<int> p45wh;
assign(p45wh, rectangle_data<int>(interval_data<int>(0, 10), interval_data<int>(20, 30)));
if(winding(p45wh) != COUNTERCLOCKWISE) return false;
polygon_45_with_holes_data<int> p45;
assign(p45, rectangle_data<int>(interval_data<int>(0, 10), interval_data<int>(20, 30)));
if(winding(p45) != COUNTERCLOCKWISE) return false;
polygon_45_with_holes_data<int> p;
assign(p, rectangle_data<int>(interval_data<int>(0, 10), interval_data<int>(20, 30)));
if(winding(p) != COUNTERCLOCKWISE) return false;
set_compact(p45wh, rect, rect+4);
if(winding(p45wh) != COUNTERCLOCKWISE) return false;
points.clear();
points.push_back(point_data<int>(0, 0));
points.push_back(point_data<int>(10, 10));
points.push_back(point_data<int>(0, 20));
points.push_back(point_data<int>(-10, 10));
set_points(p45, points.begin(), points.end());
if(winding(p45) != COUNTERCLOCKWISE) return false;
std::swap(points[1], points[3]);
set_points(p, points.begin(), points.end());
if(winding(p) == COUNTERCLOCKWISE) return false;
point_data<int> cp;
center(cp, p);
if(cp != point_data<int>(0, 10)) return false;
move(p, HORIZONTAL, 3);
rectangle_data<int> bounding_box;
extents(bounding_box, p);
if(bounding_box != rectangle_data<int>(interval_data<int>(-7, 13), interval_data<int>(0, 20))) return false;
if(area(p45wh) != 400) return false;
if(area(p45) != 200) return false;
if(perimeter(p45wh) != 80) return false;
return true;
}
using namespace gtl;
typedef int Unit;
typedef point_data<int> Point;
typedef interval_data<int> Interval;
typedef rectangle_data<int> Rectangle;
typedef polygon_90_data<int> Polygon;
typedef polygon_90_with_holes_data<int> PolygonWithHoles;
typedef polygon_45_data<int> Polygon45;
typedef polygon_45_with_holes_data<int> Polygon45WithHoles;
typedef polygon_90_set_data<int> PolygonSet;
typedef polygon_45_set_data<int> Polygon45Set;
typedef axis_transformation AxisTransform;
typedef transformation<int> Transform;
bool getRandomBool() {
return rand()%2 != 0;
}
int getRandomInt() {
return rand()%6-2;
}
Point getRandomPoint() {
int x = rand()%8;
int y = rand()%8;
return Point(x, y);
}
Polygon45 getRandomTriangle() {
Point pts[3];
pts[0] = getRandomPoint();
pts[1] = pts[2] = pts[0];
int disp = getRandomInt();
bool dir = getRandomBool();
x(pts[2], x(pts[2]) + disp);
x(pts[1], x(pts[1]) + disp);
if(dir)
y(pts[1], y(pts[1]) + disp);
else
y(pts[1], y(pts[1]) - disp);
return Polygon45(pts, pts+3);
}
bool nonInteger45StessTest() {
for(unsigned int tests = 0; tests < 10; ++tests) {
Polygon45Set ps1, ps2;
std::vector<Polygon45> p45s;
for(unsigned int i = 0; i < 10; ++i) {
Polygon45 p45 = getRandomTriangle();
p45s.push_back(p45);
ps1.insert(p45);
scale_up(p45, 2);
ps2.insert(p45);
}
std::vector<Polygon45> polys;
ps1.get(polys);
Polygon45Set ps3;
for(unsigned int i = 0; i < polys.size(); ++i) {
scale_up(polys[i], 2);
ps3.insert(polys[i]);
}
Polygon45Set ps4 = ps3 ^ ps2;
std::vector<Polygon45> polys_error;
ps4.get(polys_error);
for(unsigned int i = 0; i < polys_error.size(); ++i) {
//if(polys_error[i].size() > 3) return false;
if(area(polys_error[i]) != 1) {
if(area(polys_error[i]) == 2) {
//if two area 1 errors merge it will have area 2
continue;
}
std::cout << "test failed\n";
for(unsigned int j =0; j < p45s.size(); ++j) {
std::cout << p45s[j] << std::endl;
}
return false;
}
}
}
return true;
}
bool validate_polygon_set_op(Polygon45Set& ps45_o,
const Polygon45Set& ps45_1,
const Polygon45Set& ps45_2,
int op_type) {
Polygon45Set s_ps_45_o(ps45_o);
Polygon45Set s_ps_45_1(ps45_1);
Polygon45Set s_ps_45_2(ps45_2);
s_ps_45_o.scale_up(2);
s_ps_45_1.scale_up(2);
s_ps_45_2.scale_up(2);
Polygon45Set s_ps_45_validate;
if(op_type == 0) {
s_ps_45_validate = s_ps_45_1 + s_ps_45_2;
s_ps_45_validate += Rectangle(4, 4, 6, 6);
} else if(op_type == 1) {
s_ps_45_validate = s_ps_45_1 * s_ps_45_2;
s_ps_45_validate -= Rectangle(4, 4, 6, 6);
} else if(op_type == 2) {
s_ps_45_validate = s_ps_45_1 ^ s_ps_45_2;
s_ps_45_validate -= Rectangle(4, 4, 6, 6);
} else {
s_ps_45_validate = s_ps_45_1 - s_ps_45_2;
s_ps_45_validate -= Rectangle(4, 4, 6, 6);
}
if(s_ps_45_validate != s_ps_45_o) {
std::cout << "TEST FAILED\n";
std::vector<Polygon45> polys;
s_ps_45_o.get(polys);
std::cout << "Result:\n";
for(unsigned int i = 0; i < polys.size(); ++i) {
std::cout << polys[i] << std::endl;
}
polys.clear();
s_ps_45_validate.get(polys);
std::cout << "Expected Result:\n";
for(unsigned int i = 0; i < polys.size(); ++i) {
std::cout << polys[i] << std::endl;
}
//redo the operation, set breakpoints here
switch (op_type) {
case 0:
ps45_o = ps45_1 + ps45_2;
ps45_o.get(polys);//needed to force clean
break;
case 1:
ps45_o = ps45_1 * ps45_2;
break;
case 2:
ps45_o = ps45_1 ^ ps45_2;
break;
default:
ps45_o = ps45_1 - ps45_2;
};
//redo the check, set breakpoints here
if(op_type == 0) {
s_ps_45_validate = s_ps_45_1 + s_ps_45_2;
s_ps_45_validate += Rectangle(4, 4, 6, 6);
s_ps_45_validate.get(polys);
} else if(op_type == 1) {
s_ps_45_validate = s_ps_45_1 * s_ps_45_2;
s_ps_45_validate -= Rectangle(4, 4, 6, 6);
} else if(op_type == 2) {
s_ps_45_validate = s_ps_45_1 ^ s_ps_45_2;
s_ps_45_validate -= Rectangle(4, 4, 6, 6);
} else {
s_ps_45_validate = s_ps_45_1 - s_ps_45_2;
s_ps_45_validate -= Rectangle(4, 4, 6, 6);
}
return false;
}
return true;
}
bool test_two_polygon_sets(const Polygon45Set& ps45_1,
const Polygon45Set& ps45_2) {
std::cout << "test two polygon sets \n";
std::vector<Polygon45> polys;
ps45_1.get(polys);
std::cout << "LVALUE:\n";
for(unsigned int i = 0; i < polys.size(); ++i) {
std::cout << polys[i] << std::endl;
}
polys.clear();
ps45_2.get(polys);
std::cout << "RVALUE:\n";
for(unsigned int i = 0; i < polys.size(); ++i) {
std::cout << polys[i] << std::endl;
}
Polygon45Set ps45_o;
std::cout << "OR\n";
ps45_o = ps45_1 + ps45_2;
polys.clear();
ps45_o.get(polys);
for(unsigned int i = 0; i < polys.size(); ++i) {
std::cout << polys[i] << std::endl;
}
if(!validate_polygon_set_op(ps45_o, ps45_1, ps45_2, 0)) return false;
std::cout << "AND\n";
ps45_o = ps45_1 * ps45_2;
polys.clear();
ps45_o.get(polys);
for(unsigned int i = 0; i < polys.size(); ++i) {
std::cout << polys[i] << std::endl;
}
if(!validate_polygon_set_op(ps45_o, ps45_1, ps45_2, 1)) return false;
std::cout << "XOR\n";
ps45_o = ps45_1 ^ ps45_2;
polys.clear();
ps45_o.get(polys);
for(unsigned int i = 0; i < polys.size(); ++i) {
std::cout << polys[i] << std::endl;
}
if(!validate_polygon_set_op(ps45_o, ps45_1, ps45_2, 2)) return false;
std::cout << "SUBTRACT\n";
ps45_o = ps45_1 - ps45_2;
polys.clear();
ps45_o.get(polys);
for(unsigned int i = 0; i < polys.size(); ++i) {
std::cout << polys[i] << std::endl;
}
if(!validate_polygon_set_op(ps45_o, ps45_1, ps45_2, 3)) return false;
return true;
}
bool test_two_polygons(const Polygon45& p45_1,
const Polygon45& p45_2) {
Polygon45Set ps45_1, ps45_2;
ps45_1.insert(p45_1);
ps45_2.insert(p45_2);
ps45_1.insert(rectangle_data<int>(10, -100, 20, 100));
ps45_2.insert(rectangle_data<int>(0, 10, 100, 20));
if(!test_two_polygon_sets(ps45_1, ps45_2)) return false;
Polygon45Set ps45_1_c = ps45_1 - Rectangle(0, 0, 2, 5);
Polygon45Set ps45_2_c = ps45_2 - Rectangle(0, 0, 2, 5);
if(!test_two_polygon_sets(ps45_1_c, ps45_2_c)) return false;
if(!test_two_polygon_sets(ps45_1_c, ps45_2)) return false;
if(!test_two_polygon_sets(ps45_1, ps45_2_c)) return false;
return true;
}
bool test_45_touch() {
using namespace gtl;
connectivity_extraction_45<int> ce;
rectangle_data<int> rect1(0, 0, 10, 10);
rectangle_data<int> rect2(5, 5, 15, 15);
rectangle_data<int> rect3(5, 20, 15, 25);
ce.insert(rect1);
ce.insert(rect2);
ce.insert(rect3);
std::vector<std::set<int> > graph(3);
ce.extract(graph);
if(graph[0].size() == 1 && graph[1].size() == 1 && graph[2].size() == 0) {
std::set<int>::iterator itr = graph[0].begin();
std::cout << *itr << std::endl;
std::set<int>::iterator itr1 = graph[1].begin();
std::cout << *itr1 << std::endl;
return true;
}
std::cout << "test failed\n";
return false;
}
bool test_45_touch_ur() {
using namespace gtl;
connectivity_extraction_45<int> ce;
rectangle_data<int> rect1(0, 0, 5, 5);
rectangle_data<int> rect2(5, 5, 10, 10);
ce.insert(rect1);
ce.insert(rect2);
std::vector<std::set<int> > graph(2);
ce.extract(graph);
if(graph[0].size() == 1 && graph[1].size() == 1) {
std::set<int>::iterator itr = graph[0].begin();
std::cout << *itr << std::endl;
std::set<int>::iterator itr1 = graph[1].begin();
std::cout << *itr1 << std::endl;
return true;
}
std::cout << "test failed\n";
return false;
}
bool test_45_touch_r() {
using namespace gtl;
connectivity_extraction_45<int> ce;
rectangle_data<int> rect1(0, 0, 5, 5);
rectangle_data<int> rect2(5, 0, 10, 5);
ce.insert(rect1);
ce.insert(rect2);
std::vector<std::set<int> > graph(2);
ce.extract(graph);
if(graph[0].size() == 1 && graph[1].size() == 1) {
std::set<int>::iterator itr = graph[0].begin();
std::cout << *itr << std::endl;
std::set<int>::iterator itr1 = graph[1].begin();
std::cout << *itr1 << std::endl;
return true;
}
std::cout << "test failed\n";
return false;
}
bool test_45_touch_boundaries() {
using namespace gtl;
connectivity_extraction_45<int> ce;
rectangle_data<int> rect1(0, 0, 10, 10);
rectangle_data<int> rect2(10, 0, 20, 10);
rectangle_data<int> rect3(20, 0, 30, 10);
rectangle_data<int> rect4(0, 10, 10, 20);
rectangle_data<int> rect5(10, 10, 20, 20);
rectangle_data<int> rect6(20, 10, 30, 20);
rectangle_data<int> rect7(0, 20, 10, 30);
rectangle_data<int> rect8(10, 20, 20, 30);
rectangle_data<int> rect9(20, 20, 30, 30);
ce.insert(rect1);
ce.insert(rect2);
ce.insert(rect3);
ce.insert(rect4);
ce.insert(rect5);
ce.insert(rect6);
ce.insert(rect7);
ce.insert(rect8);
ce.insert(rect9);
std::vector<std::set<int> > graph(9);
ce.extract(graph);
for(unsigned int i = 0; i < 9; ++i) {
std::cout << i << ": ";
for(std::set<int>::iterator itr = graph[i].begin(); itr != graph[i].end(); ++itr) {
std::cout << *itr << " ";
} std::cout << std::endl;
}
if(graph[0].size() == 3 && graph[1].size() == 5 && graph[2].size() == 3 &&
graph[3].size() == 5 && graph[4].size() == 8 && graph[5].size() == 5 &&
graph[6].size() == 3 && graph[7].size() == 5 && graph[8].size() == 3) {
return true;
}
std::cout << "test failed\n";
return false;
}
bool test_45_concept_interact() {
using namespace gtl;
std::vector<polygon_45_data<int> > polys;
polys += rectangle_data<int>(10, 10, 20, 20);
polys += rectangle_data<int>(15, 15, 25, 25);
polys += rectangle_data<int>(5, 25, 10, 35);
interact(polys, rectangle_data<int>(0, 0, 13, 13));
if(polys.size() != 1) return false;
return true;
}
bool test_aa_touch() {
using namespace gtl;
connectivity_extraction<int> ce;
rectangle_data<int> rect1(0, 0, 10, 10);
rectangle_data<int> rect2(5, 5, 15, 15);
rectangle_data<int> rect3(5, 20, 15, 25);
ce.insert(rect1);
ce.insert(rect2);
ce.insert(rect3);
std::vector<std::set<int> > graph(3);
ce.extract(graph);
if(graph[0].size() == 1 && graph[1].size() == 1 && graph[2].size() == 0) {
std::set<int>::iterator itr = graph[0].begin();
std::cout << *itr << std::endl;
std::set<int>::iterator itr1 = graph[1].begin();
std::cout << *itr1 << std::endl;
return true;
}
std::cout << "test failed\n";
return false;
}
bool test_aa_touch_ur() {
using namespace gtl;
connectivity_extraction<int> ce;
rectangle_data<int> rect1(0, 0, 5, 5);
rectangle_data<int> rect2(5, 5, 10, 10);
ce.insert(rect1);
ce.insert(rect2);
std::vector<std::set<int> > graph(2);
ce.extract(graph);
if(graph[0].size() == 1 && graph[1].size() == 1) {
std::set<int>::iterator itr = graph[0].begin();
std::cout << *itr << std::endl;
std::set<int>::iterator itr1 = graph[1].begin();
std::cout << *itr1 << std::endl;
return true;
}
std::cout << "test failed\n";
return false;
}
bool test_aa_touch_ur2() {
using namespace gtl;
connectivity_extraction<int> ce;
rectangle_data<int> rect2(5, 5, 10, 10);
point_data<int> pts[3] = {
point_data<int>(0, 0),
point_data<int>(5, 5),
point_data<int>(0, 5)
};
polygon_data<int> poly;
poly.set(pts, pts+3);
ce.insert(poly);
ce.insert(rect2);
std::vector<std::set<int> > graph(2);
ce.extract(graph);
if(graph[0].size() == 1 && graph[1].size() == 1) {
std::set<int>::iterator itr = graph[0].begin();
std::cout << *itr << std::endl;
std::set<int>::iterator itr1 = graph[1].begin();
std::cout << *itr1 << std::endl;
return true;
}
std::cout << "test failed\n";
return false;
}
bool test_aa_touch_r() {
using namespace gtl;
connectivity_extraction<int> ce;
rectangle_data<int> rect1(0, 0, 5, 5);
rectangle_data<int> rect2(5, 0, 10, 5);
ce.insert(rect1);
ce.insert(rect2);
std::vector<std::set<int> > graph(2);
ce.extract(graph);
if(graph[0].size() == 1 && graph[1].size() == 1) {
std::set<int>::iterator itr = graph[0].begin();
std::cout << *itr << std::endl;
std::set<int>::iterator itr1 = graph[1].begin();
std::cout << *itr1 << std::endl;
return true;
}
std::cout << "test failed\n";
return false;
}
bool test_aa_touch_boundaries() {
using namespace gtl;
connectivity_extraction<int> ce;
rectangle_data<int> rect1(0, 0, 10, 10);
rectangle_data<int> rect2(10, 0, 20, 10);
rectangle_data<int> rect3(20, 0, 30, 10);
rectangle_data<int> rect4(0, 10, 10, 20);
rectangle_data<int> rect5(10, 10, 20, 20);
rectangle_data<int> rect6(20, 10, 30, 20);
rectangle_data<int> rect7(0, 20, 10, 30);
rectangle_data<int> rect8(10, 20, 20, 30);
rectangle_data<int> rect9(20, 20, 30, 30);
ce.insert(rect1);
ce.insert(rect2);
ce.insert(rect3);
ce.insert(rect4);
ce.insert(rect5);
ce.insert(rect6);
ce.insert(rect7);
ce.insert(rect8);
ce.insert(rect9);
std::vector<std::set<int> > graph(9);
ce.extract(graph);
for(unsigned int i = 0; i < 9; ++i) {
std::cout << i << ": ";
for(std::set<int>::iterator itr = graph[i].begin(); itr != graph[i].end(); ++itr) {
std::cout << *itr << " ";
} std::cout << std::endl;
}
if(graph[0].size() == 3 && graph[1].size() == 5 && graph[2].size() == 3 &&
graph[3].size() == 5 && graph[4].size() == 8 && graph[5].size() == 5 &&
graph[6].size() == 3 && graph[7].size() == 5 && graph[8].size() == 3) {
return true;
}
std::cout << "test failed\n";
return false;
}
bool test_aa_concept_interact() {
using namespace gtl;
std::vector<polygon_data<int> > polys;
polys += rectangle_data<int>(10, 10, 20, 20);
polys += rectangle_data<int>(15, 15, 25, 25);
polys += rectangle_data<int>(5, 25, 10, 35);
interact(polys, rectangle_data<int>(0, 0, 13, 13));
if(polys.size() != 1) return false;
return true;
}
bool test_get_rectangles() {
using namespace gtl;
polygon_90_set_data<int> ps(VERTICAL);
ps += rectangle_data<int>(0, 0, 10, 10);
ps += rectangle_data<int>(5, 5, 15, 15);
std::vector<polygon_90_data<int> > polys;
ps.get_rectangles(polys, HORIZONTAL);
for(unsigned int i = 0; i < polys.size(); ++i) {
std::cout << polys[i] << std::endl;
}
if(polys.size() != 3) return false;
std::vector<rectangle_data<int> > rects;
ps.get_rectangles(rects, HORIZONTAL);
for(unsigned int i = 0; i < rects.size(); ++i) {
std::cout << rects[i] << std::endl;
}
if(rects.size() != 3) return false;
if(!equivalence(rects[2], rectangle_data<int>(5,10,15,15))) return false;
get_rectangles(polys, rects, VERTICAL);
get_rectangles(rects, polys, HORIZONTAL);
return equivalence(rects, polys);
}
bool test_get_trapezoids() {
using namespace gtl;
polygon_45_set_data<int> ps;
ps += rectangle_data<int>(0, 0, 10, 10);
ps += rectangle_data<int>(5, 5, 15, 15);
std::vector<polygon_45_data<int> > polys;
ps.get_trapezoids(polys, HORIZONTAL);
for(unsigned int i = 0; i < polys.size(); ++i) {
std::cout << polys[i] << std::endl;
}
if(polys.size() != 3) return false;
std::vector<polygon_45_data<int> > rects;
ps.get_trapezoids(rects, HORIZONTAL);
for(unsigned int i = 0; i < rects.size(); ++i) {
std::cout << rects[i] << std::endl;
}
if(rects.size() != 3) return false;
if(!equivalence(rects[2], rectangle_data<int>(5,10,15,15))) return false;
get_trapezoids(polys, rects, VERTICAL);
get_trapezoids(rects, polys, HORIZONTAL);
return equivalence(rects, polys);
}
bool test_SQRT1OVER2() {
Point pts[] = {
Point(100, 100),
Point(0, 100),
Point(100, 200),
Point(0, 300),
Point(100, 400),
Point(0, 500),
Point(100, 500),
Point(100, 600),
Point(200, 500),
Point(300, 600),
Point(400, 500),
Point(500, 600),
Point(500, 500),
Point(600, 500),
Point(500, 400),
Point(600, 300),
Point(500, 200),
Point(600, 100),
Point(500, 100),
Point(500, 0),
Point(400, 100),
Point(300, 0),
Point(200, 100),
Point(100, 0),
Point(100, 100)
};
Polygon45 p45(pts, pts+25);
std::cout << is_45(p45) << std::endl;
std::cout << p45 << std::endl;
Polygon45Set ps45;
ps45 += p45;
ps45.resize(10, SQRT1OVER2, ORTHOGONAL);
std::vector<Polygon45> polys;
ps45.get(polys);
if(polys.size() != 1) return false;
Point pts2[] = {
Point(90, 90),
Point(-10, 90),
Point(-10, 100),
Point(90, 200),
Point(-10, 300),
Point(90, 400),
Point(-10, 500),
Point(-10, 510),
Point(90, 510),
Point(90, 610),
Point(100, 610),
Point(200, 510),
Point(300, 610),
Point(400, 510),
Point(500, 610),
Point(510, 610),
Point(510, 510),
Point(610, 510),
Point(610, 500),
Point(510, 400),
Point(610, 300),
Point(510, 200),
Point(610, 100),
Point(610, 90),
Point(510, 90),
Point(510, -10),
Point(500, -10),
Point(400, 90),
Point(300, -10),
Point(200, 90),
Point(100, -10),
Point(90, -10),
Point(90, 90)
};
Polygon45 p45reference(pts2, pts2+33);
std::cout << is_45(polys[0]) << std::endl;
std::cout << polys[0] << std::endl;
std::cout << p45reference << std::endl;
std::cout << is_45(p45reference) << std::endl;
if(!equivalence(polys[0], p45reference)) {
std::cout << "polys don't match\n";
return false;
}
ps45.resize(-10, SQRT1OVER2, ORTHOGONAL);
polys.clear();
ps45.get(polys);
if(polys.size() != 1) return false;
std::cout << is_45(polys[0]) << std::endl;
std::cout << polys[0] << std::endl;
if(!equivalence(polys[0], p45)) {
std::cout << "polys don't match\n";
return false;
}
ps45.resize(11, SQRT1OVER2, UNFILLED);
polys.clear();
ps45.get(polys);
if(polys.size() != 1) return false;
std::cout << is_45(polys[0]) << std::endl;
std::cout << polys[0] << std::endl;
return true;
}
bool test_scaling_by_floating(){
Point pts[] = {
Point(1, 1),
Point(10, 1),
Point(1, 10)
};
Polygon45 poly(pts, pts+3);
Polygon45Set ps45;
ps45 += poly;
ps45.scale(double(2.5));
std::vector<Polygon45> polys;
ps45.get(polys);
for(unsigned int i = 0; i < polys.size(); ++i) {
std::cout << polys[i] << std::endl;
std::cout << area(polys[i]) << std::endl;
}
if(polys.size() != 1) return false;
if(area(polys[0]) != 242) return false;
scale(ps45, double(1)/double(2.5));
polys.clear();
ps45.get(polys);
for(unsigned int i = 0; i < polys.size(); ++i) {
std::cout << polys[i] << std::endl;
}
return equivalence(polys, poly);
}
bool test_directional_resize() {
std::vector<Rectangle> rects;
rects.push_back(Rectangle(0, 0, 100, 100));
resize(rects, -10, 10, -10, 10);
for(unsigned int i = 0; i < rects.size(); ++i) {
std::cout << rects[i] << std::endl;
}
if(rects.size() != 1) return false;
if(rects[0] != Rectangle(10, 10, 110, 110)) return false;
return true;
}
bool test_self_xor() {
std::vector<Rectangle> rects;
rects.push_back(Rectangle(0, 0, 10, 10));
rects.push_back(Rectangle(5, 5, 15, 15));
self_xor(rects);
for(unsigned int i = 0; i < rects.size(); ++i) {
std::cout << rects[i] << std::endl;
}
if(rects.size() == 4) return true;
else return false;
}
bool test_grow_and_45() {
polygon_45_set_data<int> ps;
ps.insert(Rectangle(0, 0, 5, 5));
ps.insert(Rectangle(5, 5, 15, 15));
grow_and(ps, 2);
std::vector<polygon_45_data<int> > rects;
ps.get_trapezoids(rects);
for(unsigned int i = 0; i < rects.size(); ++i) {
std::cout << rects[i] << std::endl;
}
if(rects.size() != 1) return false;
return equivalence(rects, Rectangle(3, 3, 7, 7));
}
bool test_self_xor_45() {
polygon_45_set_data<int> ps;
ps.insert(Rectangle(0, 0, 10, 10));
ps.insert(Rectangle(5, 5, 15, 15));
self_xor(ps);
std::vector<polygon_45_data<int> > rects;
ps.get_trapezoids(rects);
for(unsigned int i = 0; i < rects.size(); ++i) {
std::cout << rects[i] << std::endl;
}
if(rects.size() == 4) return true;
else return false;
}
bool testViewCopyConstruct() {
PolygonSet ps1, ps2;
ps1.insert(Rectangle(0, 0, 10, 10));
ps2.insert(Rectangle(5, 5, 15, 15));
PolygonSet psr = ps1 - ps2;
std::vector<Rectangle> rects;
rects += psr;
for(unsigned int i = 0; i < rects.size(); ++i)
std::cout << rects[i] << std::endl;
if( rects.size() != 2) return false;
Polygon45Set ps45_1, ps45_2;
ps45_1.insert(Rectangle(0, 0, 10, 10));
ps45_2.insert(Rectangle(5, 5, 15, 15));
Polygon45Set ps45_r = ps45_1 - ps45_2;
std::vector<Polygon45> polys;
ps45_r.get_trapezoids(polys);
for(unsigned int i = 0; i < polys.size(); ++i)
std::cout << polys[i] << std::endl;
if( polys.size() != 2) return false;
return true;
}
bool testpip() {
std::vector<Point> pts;
pts.push_back(Point(0, 0));
pts.push_back(Point(10, 0));
pts.push_back(Point(20, 10));
pts.push_back(Point(0, 20));
pts.push_back(Point(30, 40));
pts.push_back(Point(-10, 50));
pts.push_back(Point(-20, -20));
pts.push_back(Point(0, 0));
polygon_data<int> poly;
polygon_with_holes_data<int> poly2;
polygon_45_data<int> poly45;
polygon_45_with_holes_data<int> poly245;
polygon_90_data<int> poly90;
polygon_90_with_holes_data<int> poly290;
poly.set(pts.begin(), pts.end());
poly2.set(pts.begin(), pts.end());
assign(poly45, Rectangle(0, 0, 100, 100));
assign(poly245, Rectangle(0, 0, 100, 100));
assign(poly90, Rectangle(0, 0, 100, 100));
assign(poly290, Rectangle(0, 0, 100, 100));
for(unsigned int i = 0; i < pts.size(); ++i) {
if(!contains(poly, pts[i], true)) return false;
if(contains(poly, pts[i], false)) return false;
if(!contains(poly2, pts[i], true)) return false;
if(contains(poly2, pts[i], false)) return false;
}
if(!contains(poly45, pts[0], true)) return false;
if(contains(poly245, pts[0], false)) return false;
if(!contains(poly90, pts[0], true)) return false;
if(contains(poly290, pts[0], false)) return false;
Point pt(0, -10);
if(contains(poly, pt)) return false;
Point p2(0, 1);
if(!contains(poly, p2)) return false;
return true;
}
void testHand() {
using namespace gtl;
int handcoords[] = {
12375, 11050, 13175, 10200, 15825, 9275, 18750, 8525, 24150, 8300, 27575, 8400, 31775, 7800,
35975, 7200, 41375, 4800, 42575, 4200, 43175, 4200, 47375, 2400, 49175, 1800, 51150, 2200,
52275, 2825, 52625, 4150, 52375, 4975, 51575, 6000, 49275, 6850, 45700, 7950, 43175, 9600,
39575, 10800, 37775, 12000, 37775, 12600, 37775, 13800, 38975, 14400, 41375, 14400, 45575, 13200,
48600, 13000, 51575, 13200, 55175, 12600, 58775, 12600, 61175, 13200, 62375, 14400, 62550, 15700,
61975, 16875, 60775, 17600, 60100, 17675, 58525, 17675, 56150, 17575, 52175, 18000, 47975, 18600,
45575, 19200, 44375, 19200, 42675, 19325, 41600, 19775, 41600, 20500, 42100, 20825, 44975, 20400,
48575, 20400, 52775, 21000, 53975, 21000, 57575, 21000, 62375, 21000, 65450, 22000, 66300, 23100,
66100, 24550, 64750, 25925, 62975, 26400, 61175, 26400, 58775, 26400, 56025, 26050, 53450, 26025,
50975, 26400, 48575, 26400, 46775, 26400, 43650, 26075, 41375, 26400, 40775, 27000, 40775, 27600,
42225, 28650, 44375, 29400, 48575, 30000, 50975, 31200, 53975, 31800, 58775, 33000, 61200, 34300,
62375, 35400, 62375, 37200, 61175, 38400, 60000, 38700, 57575, 38400, 54550, 37575, 50975, 36600,
49075, 36125, 47750, 36125, 45700, 35425, 42350, 34350, 38900, 33775, 30575, 33000, 26975, 33600,
25975, 34900, 26375, 36600, 28175, 38400, 30575, 40800, 32375, 43800, 33200, 46200, 33200, 48000,
32650, 49300, 31425, 50000, 29950, 50125, 28825, 49375, 27575, 48000, 25825, 46000, 23975, 44100,
22175, 42600, 19775, 39600, 17325, 37300, 14975, 34800, 13175, 31800, 10775, 29400, 9600, 27400,
10175, 27000, 11375, 27600, 12575, 28800, 14375, 31800, 16175, 34800, 18575, 37200, 21575, 39000,
22775, 40200, 23975, 41400, 24575, 42600, 26375, 44400, 28325, 46000, 29850, 46775, 31175, 46200,
31550, 44575, 30575, 43200, 28775, 40800, 25775, 38400, 24575, 34800, 24750, 33175, 26975, 31800,
29975, 31800, 33575, 31800, 37775, 32400, 39575, 33000, 41975, 33600, 45150, 34175, 46975, 34750,
48575, 35400, 50975, 35400, 51575, 34800, 51875, 33725, 50775, 32575, 48575, 31800, 45750, 30875,
43775, 30600, 41375, 29400, 38975, 28800, 35975, 28200, 34775, 27600, 34175, 27000, 34775, 25800,
37175, 25200, 40175, 25200, 43175, 25200, 46775, 25200, 50975, 25425, 53375, 25200, 55175, 24600,
55525, 23450, 53975, 22200, 52775, 22200, 49075, 21850, 45950, 21925, 40775, 21600, 37775, 21600,
35150, 21350, 34325, 20950, 34175, 19800, 35975, 19200, 38375, 19200, 40750, 18900, 42575, 18600,
44375, 18000, 47975, 17400, 50375, 17125, 52025, 16625, 52775, 15600, 52100, 14625, 49675, 14125,
48625, 14125, 46775, 14400, 44375, 15000, 41375, 15150, 37700, 15275, 34775, 15600, 32850, 15925,
31775, 15600, 31425, 14875, 32375, 13800, 36575, 11400, 38975, 10200, 41375, 9000, 43075, 8150,
43650, 7200, 43325, 6250, 42225, 5825, 40800, 6275, 38900, 6925, 35375, 8400, 32375, 10200,
27575, 11400, 22775, 12600, 19775, 13225, 16775, 13800, 14975, 14400, 13050, 14000, 11975, 12600,
0, 0 };
std::vector<Point> handpoints;
for(unsigned int i = 0; i < 100000; i += 2) {
Point pt(handcoords[i], handcoords[i+1]);
if(pt == Point(0, 0)) break;
handpoints.push_back(pt);
}
polygon_data<int> handpoly;
handpoly.set(handpoints.begin(), handpoints.end());
int spiralcoords [] = {
37200, 3600, 42075, 4025, 47475, 5875, 51000, 7800, 55800, 12300, 59000, 17075, 60000, 20400,
61200, 25800, 61200, 29400, 60600, 33600, 58800, 38400, 55800, 42600, 53200, 45625,
49200, 48600, 43200, 51000, 35400, 51600, 29400, 50400, 23400, 47400, 19200, 43800,
16200, 39600, 14400, 35400, 13200, 29400, 13200, 24000, 15000, 18600, 17400, 13800,
20525, 10300, 24600, 7200, 29400, 4800, 32450, 4000, 34825, 3675, 35625, 3625,
35825, 7275, 39600, 7200, 43800, 8400, 46800, 9600, 50400, 12000, 53400, 15000,
55800, 18600, 57000, 23400, 57600, 27000, 57000, 32400, 55200, 37200, 52200, 41400,
48000, 45000, 42000, 47400, 35400, 48000, 30000, 46800, 24600, 43800, 20325, 39100,
17850, 34275, 16800, 27600, 17400, 22200, 20400, 16200, 24600, 11400, 28800, 9000,
32400, 7800, 33200, 7575, 33925, 11050, 35400, 10800, 37200, 10800, 41400, 11400,
46200, 13200, 49800, 16200, 51600, 19200, 53400, 23400, 54000, 29400, 52800, 33600,
49800, 39000, 45000, 42600, 39000, 44400, 33600, 43800, 28200, 42000, 24000, 37800,
21000, 33000, 20400, 26400, 21600, 21000, 24600, 16200, 28200, 13200, 31875, 11625,
33200, 15625, 36000, 15000, 39000, 15000, 43800, 16800, 46800, 19200, 49200, 23400,
49800, 27600, 48750, 32700, 46350, 36275, 42600, 39000, 38400, 40200, 31800, 39000,
28200, 36600, 25200, 31200, 24600, 26400, 26025, 21800, 28200, 18600, 30600, 16800,
32575, 19875, 34200, 19200, 36000, 18600, 37200, 18600, 40375, 19125, 43200, 21000,
45600, 24000, 46200, 27600, 45600, 30600, 43800, 33600, 41475, 35625, 37800, 36600,
33600, 36000, 30000, 33600, 28200, 28800, 28800, 24600, 30000, 22200, 31200, 23400,
30600, 25200, 30000, 27000, 30600, 30000, 31800, 32400, 34200, 34200, 38400, 34800,
41400, 33000, 44025, 30225, 44400, 26400, 43200, 23400, 40900, 21200, 37800, 20400,
34950, 20675, 32400, 22200, 30175, 19475, 28425, 21300, 27000, 24000, 26400, 27600,
27000, 31800, 31200, 36600, 36600, 38400, 42600, 37200, 46200, 33600, 48000, 30000,
47650, 24425, 45600, 20400, 42650, 18200, 39000, 16800, 35400, 16800, 33600, 17400,
32875, 17675, 31100, 13850, 28200, 15600, 25200, 18600, 22800, 22800, 22200, 27000,
23400, 33600, 26400, 38400, 31675, 41575, 37800, 42600, 40850, 42150, 42800, 41550,
47050, 39025, 50100, 35375, 52200, 29400, 51675, 23950, 49800, 19200, 46200, 15600,
41400, 13200, 37800, 12600, 35025, 12750, 33350, 13050, 32400, 9600, 30025, 10325,
25925, 12725, 22200, 16800, 19800, 21000, 18600, 25800, 18600, 30000, 20400, 35400,
22575, 39250, 25225, 41825, 28200, 43800, 33600, 46200, 39000, 46200, 44400, 45000,
48650, 42350, 52800, 37800, 55200, 32400, 55800, 26400, 54600, 21000, 53400, 18000,
50400, 14400, 47400, 12000, 42600, 9600, 39000, 9000, 36000, 9000, 34775, 9125,
34300, 5600, 30000, 6600, 25800, 8400, 22025, 11350, 18725, 15125, 16200, 20400,
15000, 24600, 15000, 30600, 16800, 36600, 20400, 42600, 25800, 46800, 31200, 49200,
38400, 49800, 45000, 48600, 51000, 45000, 55475, 40225, 58200, 34800, 59400, 30000,
59400, 25200, 58200, 19800, 55200, 14400, 52225, 11150, 47400, 7800, 44175, 6500,
40200, 5400, 38400, 5400, 37200, 5400, 0, 0 };
std::vector<Point> spiralpoints;
for(unsigned int i = 0; i < 100000; i += 2) {
Point pt(spiralcoords[i], spiralcoords[i+1]);
if(pt == Point(0, 0)) break;
spiralpoints.push_back(pt);
}
polygon_data<int> spiralpoly;
spiralpoly.set(spiralpoints.begin(), spiralpoints.end());
polygon_set_data<int> handset;
handset += handpoly;
polygon_set_data<int> spiralset;
spiralset += spiralpoly;
polygon_set_data<int> xorset = handset ^ spiralset;
std::vector<polygon_data<int> > polys;
polys += xorset;
std::cout << polys.size() << std::endl;
for(unsigned int i = 0; i < polys.size(); ++i)
std::cout << polys[i] << std::endl;
}
//void testHandFloat() {
// using namespace gtl;
// double handcoords[] = {
//12375, 11050, 13175, 10200, 15825, 9275, 18750, 8525, 24150, 8300, 27575, 8400, 31775, 7800,
//35975, 7200, 41375, 4800, 42575, 4200, 43175, 4200, 47375, 2400, 49175, 1800, 51150, 2200,
//52275, 2825, 52625, 4150, 52375, 4975, 51575, 6000, 49275, 6850, 45700, 7950, 43175, 9600,
//39575, 10800, 37775, 12000, 37775, 12600, 37775, 13800, 38975, 14400, 41375, 14400, 45575, 13200,
//48600, 13000, 51575, 13200, 55175, 12600, 58775, 12600, 61175, 13200, 62375, 14400, 62550, 15700,
//61975, 16875, 60775, 17600, 60100, 17675, 58525, 17675, 56150, 17575, 52175, 18000, 47975, 18600,
//45575, 19200, 44375, 19200, 42675, 19325, 41600, 19775, 41600, 20500, 42100, 20825, 44975, 20400,
//48575, 20400, 52775, 21000, 53975, 21000, 57575, 21000, 62375, 21000, 65450, 22000, 66300, 23100,
//66100, 24550, 64750, 25925, 62975, 26400, 61175, 26400, 58775, 26400, 56025, 26050, 53450, 26025,
//50975, 26400, 48575, 26400, 46775, 26400, 43650, 26075, 41375, 26400, 40775, 27000, 40775, 27600,
//42225, 28650, 44375, 29400, 48575, 30000, 50975, 31200, 53975, 31800, 58775, 33000, 61200, 34300,
//62375, 35400, 62375, 37200, 61175, 38400, 60000, 38700, 57575, 38400, 54550, 37575, 50975, 36600,
//49075, 36125, 47750, 36125, 45700, 35425, 42350, 34350, 38900, 33775, 30575, 33000, 26975, 33600,
//25975, 34900, 26375, 36600, 28175, 38400, 30575, 40800, 32375, 43800, 33200, 46200, 33200, 48000,
//32650, 49300, 31425, 50000, 29950, 50125, 28825, 49375, 27575, 48000, 25825, 46000, 23975, 44100,
//22175, 42600, 19775, 39600, 17325, 37300, 14975, 34800, 13175, 31800, 10775, 29400, 9600, 27400,
//10175, 27000, 11375, 27600, 12575, 28800, 14375, 31800, 16175, 34800, 18575, 37200, 21575, 39000,
//22775, 40200, 23975, 41400, 24575, 42600, 26375, 44400, 28325, 46000, 29850, 46775, 31175, 46200,
//31550, 44575, 30575, 43200, 28775, 40800, 25775, 38400, 24575, 34800, 24750, 33175, 26975, 31800,
//29975, 31800, 33575, 31800, 37775, 32400, 39575, 33000, 41975, 33600, 45150, 34175, 46975, 34750,
//48575, 35400, 50975, 35400, 51575, 34800, 51875, 33725, 50775, 32575, 48575, 31800, 45750, 30875,
//43775, 30600, 41375, 29400, 38975, 28800, 35975, 28200, 34775, 27600, 34175, 27000, 34775, 25800,
//37175, 25200, 40175, 25200, 43175, 25200, 46775, 25200, 50975, 25425, 53375, 25200, 55175, 24600,
//55525, 23450, 53975, 22200, 52775, 22200, 49075, 21850, 45950, 21925, 40775, 21600, 37775, 21600,
//35150, 21350, 34325, 20950, 34175, 19800, 35975, 19200, 38375, 19200, 40750, 18900, 42575, 18600,
//44375, 18000, 47975, 17400, 50375, 17125, 52025, 16625, 52775, 15600, 52100, 14625, 49675, 14125,
//48625, 14125, 46775, 14400, 44375, 15000, 41375, 15150, 37700, 15275, 34775, 15600, 32850, 15925,
//31775, 15600, 31425, 14875, 32375, 13800, 36575, 11400, 38975, 10200, 41375, 9000, 43075, 8150,
//43650, 7200, 43325, 6250, 42225, 5825, 40800, 6275, 38900, 6925, 35375, 8400, 32375, 10200,
//27575, 11400, 22775, 12600, 19775, 13225, 16775, 13800, 14975, 14400, 13050, 14000, 11975, 12600,
// 0, 0 };
// std::vector<point_data<double> > handpoints;
// for(unsigned int i = 0; i < 100000; i += 2) {
// point_data<double> pt(handcoords[i], handcoords[i+1]);
// if(pt == point_data<double> (0, 0)) break;
// handpoints.push_back(pt);
// }
// polygon_data<double> handpoly;
// handpoly.set(handpoints.begin(), handpoints.end());
// double spiralcoords [] = {
//37200, 3600, 42075, 4025, 47475, 5875, 51000, 7800, 55800, 12300, 59000, 17075, 60000, 20400,
//61200, 25800, 61200, 29400, 60600, 33600, 58800, 38400, 55800, 42600, 53200, 45625,
//49200, 48600, 43200, 51000, 35400, 51600, 29400, 50400, 23400, 47400, 19200, 43800,
//16200, 39600, 14400, 35400, 13200, 29400, 13200, 24000, 15000, 18600, 17400, 13800,
//20525, 10300, 24600, 7200, 29400, 4800, 32450, 4000, 34825, 3675, 35625, 3625,
//35825, 7275, 39600, 7200, 43800, 8400, 46800, 9600, 50400, 12000, 53400, 15000,
//55800, 18600, 57000, 23400, 57600, 27000, 57000, 32400, 55200, 37200, 52200, 41400,
//48000, 45000, 42000, 47400, 35400, 48000, 30000, 46800, 24600, 43800, 20325, 39100,
//17850, 34275, 16800, 27600, 17400, 22200, 20400, 16200, 24600, 11400, 28800, 9000,
//32400, 7800, 33200, 7575, 33925, 11050, 35400, 10800, 37200, 10800, 41400, 11400,
//46200, 13200, 49800, 16200, 51600, 19200, 53400, 23400, 54000, 29400, 52800, 33600,
//49800, 39000, 45000, 42600, 39000, 44400, 33600, 43800, 28200, 42000, 24000, 37800,
//21000, 33000, 20400, 26400, 21600, 21000, 24600, 16200, 28200, 13200, 31875, 11625,
//33200, 15625, 36000, 15000, 39000, 15000, 43800, 16800, 46800, 19200, 49200, 23400,
//49800, 27600, 48750, 32700, 46350, 36275, 42600, 39000, 38400, 40200, 31800, 39000,
//28200, 36600, 25200, 31200, 24600, 26400, 26025, 21800, 28200, 18600, 30600, 16800,
//32575, 19875, 34200, 19200, 36000, 18600, 37200, 18600, 40375, 19125, 43200, 21000,
//45600, 24000, 46200, 27600, 45600, 30600, 43800, 33600, 41475, 35625, 37800, 36600,
//33600, 36000, 30000, 33600, 28200, 28800, 28800, 24600, 30000, 22200, 31200, 23400,
//30600, 25200, 30000, 27000, 30600, 30000, 31800, 32400, 34200, 34200, 38400, 34800,
//41400, 33000, 44025, 30225, 44400, 26400, 43200, 23400, 40900, 21200, 37800, 20400,
//34950, 20675, 32400, 22200, 30175, 19475, 28425, 21300, 27000, 24000, 26400, 27600,
//27000, 31800, 31200, 36600, 36600, 38400, 42600, 37200, 46200, 33600, 48000, 30000,
//47650, 24425, 45600, 20400, 42650, 18200, 39000, 16800, 35400, 16800, 33600, 17400,
//32875, 17675, 31100, 13850, 28200, 15600, 25200, 18600, 22800, 22800, 22200, 27000,
//23400, 33600, 26400, 38400, 31675, 41575, 37800, 42600, 40850, 42150, 42800, 41550,
//47050, 39025, 50100, 35375, 52200, 29400, 51675, 23950, 49800, 19200, 46200, 15600,
//41400, 13200, 37800, 12600, 35025, 12750, 33350, 13050, 32400, 9600, 30025, 10325,
//25925, 12725, 22200, 16800, 19800, 21000, 18600, 25800, 18600, 30000, 20400, 35400,
//22575, 39250, 25225, 41825, 28200, 43800, 33600, 46200, 39000, 46200, 44400, 45000,
//48650, 42350, 52800, 37800, 55200, 32400, 55800, 26400, 54600, 21000, 53400, 18000,
//50400, 14400, 47400, 12000, 42600, 9600, 39000, 9000, 36000, 9000, 34775, 9125,
//34300, 5600, 30000, 6600, 25800, 8400, 22025, 11350, 18725, 15125, 16200, 20400,
//15000, 24600, 15000, 30600, 16800, 36600, 20400, 42600, 25800, 46800, 31200, 49200,
//38400, 49800, 45000, 48600, 51000, 45000, 55475, 40225, 58200, 34800, 59400, 30000,
//59400, 25200, 58200, 19800, 55200, 14400, 52225, 11150, 47400, 7800, 44175, 6500,
//40200, 5400, 38400, 5400, 37200, 5400, 0, 0 };
// std::vector<point_data<double> > spiralpoints;
// for(unsigned int i = 0; i < 100000; i += 2) {
// point_data<double> pt(spiralcoords[i], spiralcoords[i+1]);
// if(pt == point_data<double> (0, 0)) break;
// spiralpoints.push_back(pt);
// }
// polygon_data<double> spiralpoly;
// spiralpoly.set(spiralpoints.begin(), spiralpoints.end());
// polygon_set_data<double> handset;
// handset += handpoly;
// polygon_set_data<double> spiralset;
// spiralset += spiralpoly;
// polygon_set_data<double> xorset = handset ^ spiralset;
// std::vector<polygon_data<double> > polys;
// polys += xorset;
// std::cout << polys.size() << std::endl;
// for(unsigned int i = 0; i < polys.size(); ++i)
// std::cout << polys[i] << std::endl;
//}
bool testDirectionalSize() {
{
PolygonSet ps(VERTICAL);
ps += Rectangle(0, 0, 100, 100);
ps.resize(0, -10, 0, -10);
std::vector<Rectangle> rects;
ps.get(rects);
if(rects.size() != 1) return false;
std::cout << rects[0] << std::endl;
std::cout << Rectangle(0, 0, 90, 90) << std::endl;
if(rects[0] != Rectangle(0, 0, 90, 90)) return false;
}
{
PolygonSet ps(VERTICAL);
ps += Rectangle(0, 0, 100, 100);
ps.resize(0, 0, 0, -10);
std::vector<Rectangle> rects;
ps.get(rects);
if(rects.size() != 1) return false;
std::cout << rects[0] << std::endl;
std::cout << Rectangle(0, 0, 100, 90) << std::endl;
if(rects[0] != Rectangle(0, 0, 100, 90)) return false;
}
{
PolygonSet ps;
ps += Rectangle(0, 0, 100, 100);
ps.resize(0, -10, 0, 0);
std::vector<Rectangle> rects;
ps.get(rects);
if(rects.size() != 1) return false;
std::cout << rects[0] << std::endl;
std::cout << Rectangle(0, 0, 90, 100) << std::endl;
if(rects[0] != Rectangle(0, 0, 90, 100)) return false;
}
{
PolygonSet ps;
ps += Rectangle(0, 0, 100, 100);
ps.resize(0, 0, -10, 0);
std::vector<Rectangle> rects;
ps.get(rects);
if(rects.size() != 1) return false;
std::cout << rects[0] << std::endl;
std::cout << Rectangle(0, 10, 100, 100) << std::endl;
if(rects[0] != Rectangle(0, 10, 100, 100)) return false;
}
{
PolygonSet ps;
ps += Rectangle(0, 0, 100, 100);
ps.resize(-10, 0, 0, 0);
std::vector<Rectangle> rects;
ps.get(rects);
if(rects.size() != 1) return false;
std::cout << rects[0] << std::endl;
std::cout << Rectangle(10, 0, 100, 100) << std::endl;
if(rects[0] != Rectangle(10, 0, 100, 100)) return false;
}
{
PolygonSet ps;
ps += Rectangle(0, 0, 100, 100);
ps.resize(-10, 10, 0, 0);
std::vector<Rectangle> rects;
ps.get(rects);
if(rects.size() != 1) return false;
std::cout << rects[0] << std::endl;
std::cout << Rectangle(10, 0, 110, 100) << std::endl;
if(rects[0] != Rectangle(10, 0, 110, 100)) return false;
}
{
PolygonSet ps;
ps += Rectangle(0, 0, 100, 100);
ps.resize(-10, 10, 10, -10);
std::vector<Rectangle> rects;
ps.get(rects);
if(rects.size() != 1) return false;
std::cout << rects[0] << std::endl;
std::cout << Rectangle(10, -10, 110, 90) << std::endl;
if(rects[0] != Rectangle(10, -10, 110, 90)) return false;
}
{
PolygonSet ps;
ps += Rectangle(0, 0, 100, 100);
ps.resize(10, 10, -10, -10);
std::vector<Rectangle> rects;
ps.get(rects);
if(rects.size() != 1) return false;
std::cout << rects[0] << std::endl;
std::cout << Rectangle(-10, 10, 110, 90) << std::endl;
if(rects[0] != Rectangle(-10, 10, 110, 90)) return false;
}
return true;
}
bool testMaxCover() {
std::vector<Rectangle> rects;
rects.push_back(Rectangle(Interval(60, 124), Interval( 1, 3)));
rects.push_back(Rectangle(Interval(59, 83), Interval( 9, 28)));
rects.push_back(Rectangle(Interval(90, 124), Interval( 3, 29)));
rects.push_back(Rectangle(Interval(64, 124), Interval( 29, 35)));
rects.push_back(Rectangle(Interval(64, 102), Interval( 35, 49)));
rects.push_back(Rectangle(Interval(1, 20), Interval( 44, 60)));
rects.push_back(Rectangle(Interval(50, 102), Interval( 49, 71)));
rects.push_back(Rectangle(Interval(49, 102), Interval( 71, 72)));
rects.push_back(Rectangle(Interval(49, 94), Interval( 72, 75)));
rects.push_back(Rectangle(Interval(50, 74), Interval( 75, 81)));
rects.push_back(Rectangle(Interval(90, 127), Interval( 75, 81)));
rects.push_back(Rectangle(Interval(50, 127), Interval( 81, 82)));
rects.push_back(Rectangle(Interval(3, 7), Interval( 60, 88)));
rects.push_back(Rectangle(Interval(50, 92), Interval( 82, 94)));
rects.push_back(Rectangle(Interval(58, 92), Interval( 94, 111)));
std::vector<Rectangle> expected_result;
expected_result.push_back(Rectangle(Interval(60, 124), Interval( 1, 3)));
expected_result.push_back(Rectangle(Interval(90, 124), Interval( 1, 35)));
expected_result.push_back(Rectangle(Interval(90, 102), Interval( 1, 72)));
expected_result.push_back(Rectangle(Interval(90, 94 ), Interval(1 ,82)));
expected_result.push_back(Rectangle(Interval(90, 92), Interval( 1, 111)));
expected_result.push_back(Rectangle(Interval(59, 83 ), Interval(9, 28)));
expected_result.push_back(Rectangle(Interval(64, 124), Interval( 29, 35)));
expected_result.push_back(Rectangle(Interval(64, 102), Interval( 29, 72)));
expected_result.push_back(Rectangle(Interval(64, 94), Interval( 29, 75)));
expected_result.push_back(Rectangle(Interval(64, 74), Interval( 29, 111)));
expected_result.push_back(Rectangle(Interval(1, 20), Interval( 44, 60)));
expected_result.push_back(Rectangle(Interval(3, 7), Interval( 44, 88)));
expected_result.push_back(Rectangle(Interval(50, 102 ), Interval(49, 72)));
expected_result.push_back(Rectangle(Interval(50, 94), Interval( 49, 75)));
expected_result.push_back(Rectangle(Interval(50, 74), Interval( 49, 94)));
expected_result.push_back(Rectangle(Interval(58, 74), Interval( 49, 111)));
expected_result.push_back(Rectangle(Interval(49, 102 ), Interval(71, 72)));
expected_result.push_back(Rectangle(Interval(49, 94 ), Interval(71, 75)));
expected_result.push_back(Rectangle(Interval(90, 127), Interval( 75, 82)));
expected_result.push_back(Rectangle(Interval(50, 127), Interval( 81, 82)));
expected_result.push_back(Rectangle(Interval(50, 92), Interval( 81, 94)));
expected_result.push_back(Rectangle(Interval(58, 92), Interval( 81, 111)));
std::vector<Rectangle> result;
get_max_rectangles(result, rects);
std::cout << "result XOR clean: " << equivalence(result, rects) << std::endl;
std::cout << "expected result XOR clean: " << equivalence(expected_result, rects) << std::endl;
std::vector<Rectangle>& output = result;
std::vector<Rectangle>& voutput = expected_result;
std::sort(output.begin(), output.end(), less_rectangle_concept< Rectangle, Rectangle>());
std::sort(voutput.begin(), voutput.end(), less_rectangle_concept< Rectangle, Rectangle>());
if(output != voutput) {
std::cerr << "Max Rectangle TEST failed\n";
for(unsigned int i = 0; i < output.size(); ++i) {
std::cerr << output[i] << std::endl;
}
std::cerr << "Incorrect result\n";
for(unsigned int i = 0; i < voutput.size(); ++i) {
std::cerr << voutput[i] << std::endl;
}
std::cerr << "Max Rectangle TEST failed\n";
for(unsigned int i = 0; i < rects.size(); ++i) {
std::cout << rects[i] << std::endl;
}
return false;
}
return true;
}
void max_cover_stress_test() {
for(unsigned int k = 3; k < 20; k++) {
for(unsigned int i = 0; i < k * k; ++i) {
std::vector<Rectangle> rects, result;
//std::cout << "test " << i << std::endl;
for(unsigned int j = 0; j < k; ++j) {
int x1 = rand() % 100;
int x2 = rand() % 50;
int y1 = rand() % 100;
int y2 = rand() % 50;
rects.push_back(Rectangle(x1, y1, x1+x2, y1+y2));
//std::cout << rects.back() << std::endl;
}
get_max_rectangles(result, rects);
}
}
}
// namespace boost { namespace polygon{
// template <typename GCT, typename T>
// struct view_of {};
// template <typename T>
// struct view_of<polygon_45_concept, T> {
// const T* t;
// view_of(const T& obj) : t(&obj) {}
// typedef typename polygon_traits<T>::coordinate_type coordinate_type;
// typedef typename polygon_traits<T>::iterator_type iterator_type;
// typedef typename polygon_traits<T>::point_type point_type;
// /// Get the begin iterator
// inline iterator_type begin() const {
// return polygon_traits<T>::begin_points(*t);
// }
// /// Get the end iterator
// inline iterator_type end() const {
// return polygon_traits<T>::end_points(*t);
// }
// /// Get the number of sides of the polygon
// inline unsigned int size() const {
// return polygon_traits<T>::size(*t);
// }
// /// Get the winding direction of the polygon
// inline winding_direction winding() const {
// return polygon_traits<T>::winding(*t);
// }
// };
// template <typename T1, typename T2>
// view_of<T1, T2> view_as(const T2& obj) { return view_of<T1, T2>(obj); }
// template <typename T>
// struct geometry_concept<view_of<polygon_45_concept, T> > {
// typedef polygon_45_concept type;
// };
// template <typename T>
// struct view_of<polygon_90_concept, T> {
// const T* t;
// view_of(const T& obj) : t(&obj) {}
// typedef typename polygon_traits<T>::coordinate_type coordinate_type;
// typedef typename polygon_traits<T>::iterator_type iterator_type;
// typedef typename polygon_traits<T>::point_type point_type;
// typedef iterator_points_to_compact<iterator_type, point_type> compact_iterator_type;
// /// Get the begin iterator
// inline compact_iterator_type begin_compact() const {
// return compact_iterator_type(polygon_traits<T>::begin_points(*t),
// polygon_traits<T>::end_points(*t));
// }
// /// Get the end iterator
// inline compact_iterator_type end_compact() const {
// return compact_iterator_type(polygon_traits<T>::end_points(*t),
// polygon_traits<T>::end_points(*t));
// }
// /// Get the number of sides of the polygon
// inline unsigned int size() const {
// return polygon_traits<T>::size(*t);
// }
// /// Get the winding direction of the polygon
// inline winding_direction winding() const {
// return polygon_traits<T>::winding(*t);
// }
// };
// template <typename T>
// struct geometry_concept<view_of<polygon_90_concept, T> > {
// typedef polygon_90_concept type;
// };
// }}
using namespace gtl;
//this test fails and I'd like to get it to pass
bool test_colinear_duplicate_points() {
Point pts[6] = { Point(0, 10), Point(0, 0), Point(100, 0), Point(100, 100), Point(0, 100), Point(0, 10)};
Polygon45 p1;
p1.set(pts, pts+5);
Polygon45 pg;
pg.set(pts, pts+6);
Polygon45 p2;
p2.set(pts+1, pts+6);
std::cout << p2 << std::endl;
if(!equivalence(view_as<polygon_90_concept>(p2), view_as<polygon_90_concept>(pg))) return false;
std::cout << p1 << std::endl;
if(!equivalence(view_as<polygon_90_concept>(p1), view_as<polygon_90_concept>(pg))) return false;
return true;
}
bool test_extents() {
PolygonSet psT(gtl::VERTICAL);
//int xy[] = { 126, 69, 54, 69, 54, 81, 126, 81 };
//CPolygonQuery polygon(0, 4, xy);
//Rectangle rectIn(54, 69, 126, 81);
polygon_data<int> polygon;
std::vector<Point> pts;
pts.push_back(Point(126, 69));
pts.push_back(Point(54, 69));
pts.push_back(Point(54, 81));
pts.push_back(Point(126, 81));
psT.insert(view_as<polygon_90_concept>(polygon));
Rectangle rect, rect2;
psT.extents(rect2);
gtl::extents(rect, psT);
if (rect != rect2) {
std::cout << "gtl::Rectangles differ: " << gtl::xl(rect) << " " << gtl::xh(rect) << " " << gtl::yl(rect) << " " << gtl::yh(rect) << std::endl;
std::cout << " " << gtl::xl(rect2) << " " << gtl::xh(rect2) << " " << gtl::yl(rect2) << " " << gtl::yh(rect2) << std::endl;
return false;
}
return true;
}
bool test_extents2() {
Polygon45Set psT;
Point xy[] = { Point(130, 50), Point(50, 50), Point(50, 100), Point(119, 100),
Point(119, 59), Point(89, 89), Point(59, 59), Point(119, 59), Point(119, 100), Point(130, 100) };
Polygon45 polygon(xy, xy+10);
psT.insert(polygon);
psT += 2;
Rectangle rect, rect2;
psT.extents(rect2);
gtl::extents(rect, psT);
std::cout << "Extents: " << gtl::xl(rect) << " " << gtl::xh(rect) << " " << gtl::yl(rect) << " " << gtl::yh(rect) << std::endl;
std::cout << "Extents: " << gtl::xl(rect2) << " " << gtl::xh(rect2) << " " << gtl::yl(rect2) << " " << gtl::yh(rect2) << std::endl;
std::vector<Polygon45WithHoles> pwhs;
psT.get(pwhs);
for(unsigned int i = 0; i < pwhs.size(); ++i) {
std::cout << pwhs[i] << std::endl;
}
return gtl::equivalence(rect, rect2);
}
int main() {
test_view_as();
//this test fails and I'd like to get it to pass
//if(!test_colinear_duplicate_points()) return 1;
if(!test_extents2()) return 1;
if(!test_extents()) return 1;
if(!testMaxCover()) return 1;
//max_cover_stress_test(); //does not include functional testing
if(!testDirectionalSize()) return 1;
testHand();
//testHandFloat();
if(!testpip()) return 1;
{
PolygonSet ps;
Polygon p;
assign(ps, p);
}
if(!testViewCopyConstruct()) return 1;
if(!test_grow_and_45()) return 1;
if(!test_self_xor_45()) return 1;
if(!test_self_xor()) return 1;
if(!test_directional_resize()) return 1;
if(!test_scaling_by_floating()) return 1;
if(!test_SQRT1OVER2()) return 1;
if(!test_get_trapezoids()) return 1;
if(!test_get_rectangles()) return 1;
if(!test_45_concept_interact()) return 1;
if(!test_45_touch_r()) return 1;
if(!test_45_touch_ur()) return 1;
if(!test_45_touch()) return 1;
if(!test_45_touch_boundaries()) return 1;
{
Point pts[] = {Point(0,0), Point(5, 5), Point(5, 0)};
Polygon45 p45(pts, pts+3);
pts[1] = Point(0, 5);
Polygon45 p452(pts, pts+3);
if(!test_two_polygons(p45,p452)) return 1;
pts[2] = Point(5,5);
p45.set(pts, pts+3);
if(!test_two_polygons(p45,p452)) return 1;
pts[0] = Point(5,0);
p452.set(pts, pts+3);
if(!test_two_polygons(p45, p452)) return 1;
Point pts2[] = {Point(0,5), Point(5, 5), Point(5, 0)};
Point pts3[] = {Point(0,0), Point(5, 5), Point(5, 0)};
p45.set(pts2, pts2 + 3);
p452.set(pts3, pts3+3);
if(!test_two_polygons(p45, p452)) return 1;
Point pts4[] = {Point(0, 5), Point(3, 2), Point(3,5)};
Point pts5[] = {Point(0,0), Point(5, 5), Point(5, 0)};
p45.set(pts4, pts4+3);
p452.set(pts5, pts5+3);
if(!test_two_polygons(p45, p452)) return 1;
}
{
std::vector<point_data<int> > pts;
pts.push_back(point_data<int>(0, 0));
pts.push_back(point_data<int>(10, 0));
pts.push_back(point_data<int>(10, 10));
pts.push_back(point_data<int>(0, 10));
std::vector<point_data<int> > pts2;
pts2.push_back(point_data<int>(0, 0));
pts2.push_back(point_data<int>(10, 10));
pts2.push_back(point_data<int>(0, 20));
pts2.push_back(point_data<int>(-10, 10));
std::vector<point_data<int> > pts3;
pts3.push_back(point_data<int>(0, 0));
pts3.push_back(point_data<int>(10, 11));
pts3.push_back(point_data<int>(0, 20));
pts3.push_back(point_data<int>(-100, 8));
polygon_data<int> p, p1; p.set(pts3.begin(), pts3.end());
polygon_45_data<int> p45, p451; p45.set(pts2.begin(), pts2.end());
polygon_90_data<int> p90, p901; p90.set(pts.begin(), pts.end());
polygon_with_holes_data<int> pwh, pwh1; pwh.set(pts3.begin(), pts3.end());
polygon_45_with_holes_data<int> p45wh, p45wh1; p45wh.set(pts2.begin(), pts2.end());
polygon_90_with_holes_data<int> p90wh, p90wh1; p90wh.set(pts.begin(), pts.end());
assign(p, p90);
assign(p, p45);
assign(p1, p);
//illegal: assign(p, p90wh);
//illegal: assign(p, p45wh);
//illegal: assign(p, pwh);
assign(p45, p90);
assign(p451, p45);
//illegal: assign(p45, p);
//illegal: assign(p45, p90wh);
//illegal: assign(p45, p45wh);
//illegal: assign(p45, pwh);
assign(p901, p90);
//illegal: assign(p90, p45);
//illegal: assign(p90, p);
//illegal: assign(p90, p90wh);
//illegal: assign(p90, p45wh);
//illegal: assign(p90, pwh);
assign(pwh, p90);
assign(pwh, p45);
assign(pwh, p);
assign(pwh, p90wh);
assign(pwh, p45wh);
assign(pwh1, pwh);
assign(p45wh, p90);
assign(p45wh, p45);
//illegal: assign(p45wh, p);
assign(p45wh, p90wh);
assign(p45wh1, p45wh);
//illegal: assign(p45wh, pwh);
assign(p90wh, p90);
//illegal: assign(p90wh, p45);
//illegal: assign(p90wh, p);
assign(p90wh1, p90wh);
//illegal: assign(p90wh, p45wh);
//illegal: assign(p90wh, pwh);
pts.clear();
pts.push_back(point_data<int>(0, 0));
pts.push_back(point_data<int>(3, 0));
pts.push_back(point_data<int>(0, 1));
p.set(pts.begin(), pts.end());
std::cout << std::endl; std::cout << (area(p90));
std::cout << std::endl; std::cout << (area(p45));
std::cout << std::endl; std::cout << (area(p));
std::cout << std::endl; std::cout << (area(p90wh));
std::cout << std::endl; std::cout << (area(p45wh));
std::cout << std::endl; std::cout << (area(pwh));
std::cout << std::endl;
point_data<int> pt(1, 1);
std::cout << contains(p, pt) << std::endl;
std::cout << contains(p90, pt) << std::endl;
interval_data<int> ivl = construct<interval_data<int> >(0, 10);
std::cout << get(ivl, LOW) << std::endl;
set(ivl, HIGH, 20);
std::cout << perimeter(p) << std::endl;
if(winding(p) == LOW) std::cout << "LOW" << std::endl;
if(winding(p) == HIGH) std::cout << "HIGH" << std::endl;
rectangle_data<long long> rd;
std::cout << extents(rd, p) << std::endl;
std::cout << rd << std::endl;
boolean_op::testBooleanOr<int>();
std::vector<rectangle_data<int> > rects1, rects2;
rects2.push_back(rectangle_data<int>(0, 0, 10, 10));
print_is_polygon_90_set_concept((polygon_90_set_data<int>()));
print_is_mutable_polygon_90_set_concept((polygon_90_set_data<int>()));
print_is_polygon_90_set_concept((polygon_90_data<int>()));
print_is_polygon_90_set_concept((std::vector<polygon_90_data<int> >()));
assign(rects1, rects2);
polygon_90_set_data<int> ps90;
assign(ps90, rects2);
assign(rects2, ps90);
assign(ps90, p90);
assign(rects2, p90);
std::cout << p90 << std::endl;
for(unsigned int i = 0; i < rects2.size(); ++i) {
std::cout << rects2[i] << std::endl;
}
bloat(rects2, 10);
shrink(rects2[0], 10);
for(unsigned int i = 0; i < rects2.size(); ++i) {
std::cout << rects2[i] << std::endl;
}
move(rects2[0], HORIZONTAL, 30);
assign(rects1, rects2 + p90);
std::cout << "result of boolean or\n";
for(unsigned int i = 0; i < rects1.size(); ++i) {
std::cout << rects1[i] << std::endl;
}
rects1 -= p90;
std::cout << "result of boolean not\n";
for(unsigned int i = 0; i < rects1.size(); ++i) {
std::cout << rects1[i] << std::endl;
}
rects1 += p90;
std::cout << "result of boolean OR\n";
for(unsigned int i = 0; i < rects1.size(); ++i) {
std::cout << rects1[i] << std::endl;
}
rects1 *= p90;
std::cout << "result of boolean AND\n";
for(unsigned int i = 0; i < rects1.size(); ++i) {
std::cout << rects1[i] << std::endl;
}
rects1 ^= rects2;
std::cout << "result of boolean XOR\n";
for(unsigned int i = 0; i < rects1.size(); ++i) {
std::cout << rects1[i] << std::endl;
}
rects2.clear();
get_max_rectangles(rects2, p90);
std::cout << "result of max rectangles\n";
for(unsigned int i = 0; i < rects2.size(); ++i) {
std::cout << rects2[i] << std::endl;
}
rects2.clear();
//operator += and -= don't support polygons, so + and - should not exist
// rects2 += p90 + 6;
// std::cout << "result of resize\n";
// for(unsigned int i = 0; i < rects2.size(); ++i) {
// std::cout << rects2[i] << std::endl;
// }
// std::cout << "result of resize\n";
std::vector<polygon_90_with_holes_data<int> > polyswh1, polyswh2;
// polyswh1 += p90 -2;
// for(unsigned int i = 0; i < polyswh1.size(); ++i) {
// std::cout << polyswh1[i] << std::endl;
// }
// std::cout << "result of resize\n";
std::vector<polygon_90_data<int> > polys1, polys2;
polys1 += p90;
polys1 -= 2;
// polys1 += p90 -2;
for(unsigned int i = 0; i < polys1.size(); ++i) {
std::cout << polys1[i] << std::endl;
}
boolean_op_45<int>::testScan45(std::cout);
polygon_45_formation<int>::testPolygon45Formation(std::cout);
polygon_45_formation<int>::testPolygon45Tiling(std::cout);
axis_transformation atr;
transform(p, atr);
transform(p45, atr);
transform(p90, atr);
transform(pwh, atr);
transform(p45wh, atr);
transform(p90wh, atr);
scale_up(p, 2);
scale_up(p45, 2);
scale_up(p90, 2);
scale_up(pwh, 2);
scale_up(p45wh, 2);
scale_up(p90wh, 2);
scale_down(p, 2);
scale_down(p45, 2);
scale_down(p90, 2);
scale_down(pwh, 2);
scale_down(p45wh, 2);
scale_down(p90wh, 2);
std::vector<polygon_45_data<int> > p45s1, p45s2;
std::cout << equivalence(p45s1, p45s2) << std::endl;
std::cout << equivalence(p45, p45wh) << std::endl;
std::cout << equivalence(p90, p45wh) << std::endl;
gtl::assign(p45s1, p90);
p90 = polys1[0];
move(p90, orientation_2d(HORIZONTAL), 8);
std::cout << p90 << std::endl << p45wh << std::endl;
polygon_45_set_data<int> ps45 = p90 + p45wh;
assign(p45s1, ps45);
std::cout << "result\n";
for(unsigned int i = 0; i < p45s1.size(); ++i) {
std::cout << p45s1[i] << std::endl;
}
std::cout << equivalence(p, pwh) << std::endl;
std::cout << equivalence(p90, pwh) << std::endl;
std::cout << equivalence(p45, pwh) << std::endl;
std::cout << equivalence(pwh, pwh) << std::endl;
p + pwh;
p90 + pwh;
p45 + pwh;
std::cout << testInterval() << std::endl;
std::cout << testRectangle() << std::endl;
std::cout << testPolygon() << std::endl;
std::cout << testPropertyMerge() << std::endl;
std::cout << testPolygonAssign() << std::endl;
std::cout << testPolygonWithHoles() << std::endl;
std::cout << (polygon_arbitrary_formation<int>::testPolygonArbitraryFormationRect(std::cout)) << std::endl;
std::cout << (polygon_arbitrary_formation<int>::testPolygonArbitraryFormationP1(std::cout)) << std::endl;
std::cout << (polygon_arbitrary_formation<int>::testPolygonArbitraryFormationP2(std::cout)) << std::endl;
std::cout << (polygon_arbitrary_formation<int>::testPolygonArbitraryFormationPolys(std::cout)) << std::endl;
std::cout << (polygon_arbitrary_formation<int>::testPolygonArbitraryFormationSelfTouch1(std::cout)) << std::endl;
std::cout << (polygon_arbitrary_formation<int>::testPolygonArbitraryFormationSelfTouch2(std::cout)) << std::endl;
std::cout << (polygon_arbitrary_formation<int>::testPolygonArbitraryFormationSelfTouch3(std::cout)) << std::endl;
std::cout << (polygon_arbitrary_formation<int>::testSegmentIntersection(std::cout)) << std::endl;
std::cout << (property_merge<int, int>::test_insertion(std::cout)) << std::endl;
std::cout << (line_intersection<int>::test_verify_scan(std::cout)) << std::endl;
std::cout << (line_intersection<int>::test_validate_scan(std::cout)) << std::endl;
std::cout << (scanline<int, int>::test_scanline(std::cout)) << std::endl;
std::cout << (property_merge<int, int>::test_merge(std::cout)) << std::endl;
std::cout << (property_merge<int, int>::test_intersection(std::cout)) << std::endl;
std::cout << (polygon_arbitrary_formation<int>::testPolygonArbitraryFormationColinear(std::cout)) << std::endl;
std::cout << (property_merge<int, int>::test_manhattan_intersection(std::cout)) << std::endl;
std::cout << (test_arbitrary_boolean_op<int>(std::cout)) << std::endl;
}
{
polygon_set_data<int> psd;
rectangle_data<int> rect;
set_points(rect, point_data<int>(0, 0), point_data<int>(10, 10));
psd.insert(rect);
polygon_set_data<int> psd2;
set_points(rect, point_data<int>(5, 5), point_data<int>(15, 15));
psd2.insert(rect);
std::vector<polygon_data<int> > pv;
polygon_set_data<int> psd3;
psd3 = psd + psd2;
psd3.get(pv);
for(unsigned int i = 0; i < pv.size(); ++i) {
std::cout << pv[i] << std::endl;
}
psd += psd2;
pv.clear();
psd3.get(pv);
for(unsigned int i = 0; i < pv.size(); ++i) {
std::cout << pv[i] << std::endl;
}
}
{
polygon_90_set_data<int> psd;
rectangle_data<int> rect;
set_points(rect, point_data<int>(0, 0), point_data<int>(10, 10));
psd.insert(rect);
polygon_90_set_data<int> psd2;
set_points(rect, point_data<int>(5, 5), point_data<int>(15, 15));
psd2.insert(rect);
std::vector<polygon_90_data<int> > pv;
interact(psd, psd2);
assign(pv, psd);
for(unsigned int i = 0; i < pv.size(); ++i) {
std::cout << pv[i] << std::endl;
}
connectivity_extraction_90<int> ce;
ce.insert(pv[0]);
ce.insert(psd2);
std::vector<std::set<int> > graph(2);
ce.extract(graph);
if(graph[0].size() == 1) std::cout << "connectivity extraction is alive\n";
//std::vector<rectangle_data<long long> > lobs;
//get_max_rectangles(lobs, psd);
//if(lobs.size() == 1) std::cout << "max rectangles is alive\n";
std::vector<rectangle_data<int> > rv;
rv.push_back(rect);
set_points(rect, point_data<int>(0, 0), point_data<int>(10, 10));
rv.push_back(rect);
self_intersect(rv);
if(rv.size() == 1) {
assign(rect, rv.back());
std::cout << rect << std::endl;
}
assign(rv, rv + 1);
std::cout << rv.size() << std::endl;
if(rv.size() == 1) {
assign(rect, rv.back());
std::cout << rect << std::endl;
}
assign(rv, rv - 1);
if(rv.size() == 1) {
assign(rect, rv.back());
std::cout << rect << std::endl;
}
rv += 1;
if(rv.size() == 1) {
assign(rect, rv.back());
std::cout << rect << std::endl;
}
rv -= 1;
if(rv.size() == 1) {
assign(rect, rv.back());
std::cout << rect << std::endl;
}
rv.clear();
set_points(rect, point_data<int>(0, 0), point_data<int>(10, 10));
rv.push_back(rect);
set_points(rect, point_data<int>(12, 12), point_data<int>(20, 20));
rv.push_back(rect);
grow_and(rv, 7);
if(rv.size() == 1) {
assign(rect, rv.back());
std::cout << rect << std::endl;
}
std::cout << area(rv) << std::endl;
std::cout << area(rv) << std::endl;
scale_up(rv, 10);
std::cout << area(rv) << std::endl;
scale_down(rv, 7);
std::cout << area(rv) << std::endl;
if(rv.size() == 1) {
assign(rect, rv.back());
std::cout << rect << std::endl;
}
keep(rv, 290, 300, 7, 24, 7, 24);
if(rv.size() == 1) {
assign(rect, rv.back());
std::cout << rect << std::endl;
}
keep(rv, 300, 310, 7, 24, 7, 24);
if(rv.empty()) std::cout << "keep is alive\n";
}
{
// typedef int Unit;
// typedef point_data<int> Point;
// typedef interval_data<int> Interval;
// typedef rectangle_data<int> Rectangle;
// typedef polygon_90_data<int> Polygon;
// typedef polygon_90_with_holes_data<int> PolygonWithHoles;
// typedef polygon_45_data<int> Polygon45;
// typedef polygon_45_with_holes_data<int> Polygon45WithHoles;
// typedef polygon_90_set_data<int> PolygonSet;
// //typedef polygon_45_set_data<int> Polygon45Set;
// typedef axis_transformation AxisTransform;
// typedef transformation<int> Transform;
//test polygon45 area, polygon45 with holes area
std::vector<Point> pts;
pts.clear();
pts.push_back(Point(10, 10));
pts.push_back(Point(15, 10));
pts.push_back(Point(10, 15));
Polygon45 polyHole;
polyHole.set(pts.begin(), pts.end());
pts.clear();
pts.push_back(Point(10, 0));
pts.push_back(Point(20, 10));
pts.push_back(Point(20, 30));
pts.push_back(Point(0, 50));
pts.push_back(Point(0, 10));
Polygon45WithHoles polyWHoles;
polyWHoles.set(pts.begin(), pts.end());
polyWHoles.set_holes(&polyHole, (&polyHole)+1);
std::cout << polyWHoles << std::endl;
std::cout << area(polyWHoles) << std::endl;
std::cout << area(polyWHoles) << std::endl;
//test polygon45, polygon45with holes transform
AxisTransform atr(AxisTransform::EAST_SOUTH);
Polygon45WithHoles p45wh(polyWHoles);
transform(polyWHoles, atr);
std::cout << polyWHoles << std::endl;
Transform tr(atr);
tr.invert();
transform(polyWHoles, tr);
std::cout << polyWHoles << std::endl;
if(area(polyWHoles) != 687.5) return 1;
//test polygon, polygon with holes transform
Polygon ph;
assign(ph, Rectangle(10, 10, 20, 20));
PolygonWithHoles pwh;
assign(pwh, Rectangle(0, 0, 100, 100));
pwh.set_holes(&ph, (&ph)+1);
std::cout << area(pwh) << std::endl;
transform(pwh, atr);
std::cout << pwh << std::endl;
std::cout << area(pwh) << std::endl;
transform(pwh, tr);
std::cout << pwh << std::endl;
std::cout << area(pwh) << std::endl;
if(area(pwh) != 9900) return 1;
//test point scale up / down
Point pt(10, 10);
scale_up(pt, 25);
if(pt != Point(250, 250)) return 1;
std::cout << pt << std::endl;
scale_down(pt, 25);
if(pt != Point(10, 10)) return 1;
std::cout << pt << std::endl;
scale_down(pt, 25);
if(pt != Point(0, 0)) return 1;
std::cout << pt << std::endl;
//test polygon, polygon with holes scale up down
PolygonWithHoles tmpPwh(pwh);
scale_up(pwh, 25);
std::cout << pwh << std::endl;
scale_down(pwh, 25);
if(area(pwh) != area(tmpPwh)) return 1;
std::cout << pwh << std::endl;
scale_down(pwh, 25);
std::cout << pwh << std::endl;
//test polygon45, polygon45 with holes is45
std::cout << is_45(polyHole) << std::endl;
if(is_45(polyHole) != true) return 1;
pts.clear();
pts.push_back(Point(10, 10));
pts.push_back(Point(15, 10));
pts.push_back(Point(10, 16));
polyHole.set(pts.begin(), pts.end());
std::cout << is_45(polyHole) << std::endl;
if(is_45(polyHole) != false) return 1;
//test polygon45, polygon45 with holes snap 45
snap_to_45(polyHole);
std::cout << is_45(polyHole) << std::endl;
if(is_45(polyHole) != true) return 1;
std::cout << polyHole << std::endl;
//test polygon45, polygon45 with holes scalue up down
scale_up(polyHole, 10000);
std::cout << polyHole << std::endl;
scale_down(polyHole, 3);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 5);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 7);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 13);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 2);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 2);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 2);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 2);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 2);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_up(polyHole, 3);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 2);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 2);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 2);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 2);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
pts.clear();
pts.push_back(Point(11, 1));
pts.push_back(Point(21, 11));
pts.push_back(Point(11, 21));
pts.push_back(Point(1, 11));
polyHole.set(pts.begin(), pts.end());
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 3);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_up(polyHole, 10000);
std::cout << polyHole << std::endl;
scale_down(polyHole, 3);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 5);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 7);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 13);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 2);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 2);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 2);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 2);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 2);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_up(polyHole, 3);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 2);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 2);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 2);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
scale_down(polyHole, 2);
std::cout << is_45(polyHole) << " " << polyHole << std::endl;
if(is_45(polyHole) != true) return 1;
std::cout << is_45(polyWHoles) << " " << polyWHoles << std::endl;
if(is_45(polyWHoles) != true) return 1;
scale_up(polyWHoles, 100013);
std::cout << polyWHoles << std::endl;
scale_down(polyWHoles, 3);
std::cout << is_45(polyWHoles) << " " << polyWHoles << std::endl;
if(is_45(polyWHoles) != true) return 1;
scale_down(polyWHoles, 2);
std::cout << is_45(polyWHoles) << " " << polyWHoles << std::endl;
if(is_45(polyWHoles) != true) return 1;
scale_down(polyWHoles, 3);
std::cout << is_45(polyWHoles) << " " << polyWHoles << std::endl;
if(is_45(polyWHoles) != true) return 1;
scale_down(polyWHoles, 2);
std::cout << is_45(polyWHoles) << " " << polyWHoles << std::endl;
if(is_45(polyWHoles) != true) return 1;
scale_down(polyWHoles, 3);
std::cout << is_45(polyWHoles) << " " << polyWHoles << std::endl;
if(is_45(polyWHoles) != true) return 1;
scale_down(polyWHoles, 2);
std::cout << is_45(polyWHoles) << " " << polyWHoles << std::endl;
if(is_45(polyWHoles) != true) return 1;
scale_down(polyWHoles, 3);
std::cout << is_45(polyWHoles) << " " << polyWHoles << std::endl;
if(is_45(polyWHoles) != true) return 1;
scale_down(polyWHoles, 2);
std::cout << is_45(polyWHoles) << " " << polyWHoles << std::endl;
if(is_45(polyWHoles) != true) return 1;
scale_down(polyWHoles, 3);
std::cout << is_45(polyWHoles) << " " << polyWHoles << std::endl;
if(is_45(polyWHoles) != true) return 1;
scale_down(polyWHoles, 2);
std::cout << is_45(polyWHoles) << " " << polyWHoles << std::endl;
if(is_45(polyWHoles) != true) return 1;
scale_down(polyWHoles, 3);
std::cout << is_45(polyWHoles) << " " << polyWHoles << std::endl;
if(is_45(polyWHoles) != true) return 1;
scale_down(polyWHoles, 3);
std::cout << is_45(polyWHoles) << " " << polyWHoles << std::endl;
if(is_45(polyWHoles) != true) return 1;
scale_down(polyWHoles, 2);
std::cout << is_45(polyWHoles) << " " << polyWHoles << std::endl;
if(is_45(polyWHoles) != true) return 1;
scale_down(polyWHoles, 3);
std::cout << is_45(polyWHoles) << " " << polyWHoles << std::endl;
if(is_45(polyWHoles) != true) return 1;
scale_down(polyWHoles, 2);
std::cout << is_45(polyWHoles) << " " << polyWHoles << std::endl;
if(is_45(polyWHoles) != true) return 1;
scale_down(polyWHoles, 3);
std::cout << is_45(polyWHoles) << " " << polyWHoles << std::endl;
if(is_45(polyWHoles) != true) return 1;
scale_down(polyWHoles, 2);
std::cout << is_45(polyWHoles) << " " << polyWHoles << std::endl;
if(is_45(polyWHoles) != true) return 1;
std::cout << (boolean_op_45<Unit>::testScan45(std::cout)) << std::endl;
std::cout << (polygon_45_formation<Unit>::testPolygon45Formation(std::cout)) << std::endl;
std::cout << (polygon_45_formation<Unit>::testPolygon45Tiling(std::cout)) << std::endl;
{
PolygonSet ps;
Rectangle rect;
ps.insert(Rectangle(0, 0, 10, 10));
std::cout << area(ps) << std::endl;
if(area(ps) != 100) return 1;
scale_up(ps, 3);
std::cout << area(ps) << std::endl;
if(area(ps) != 900) return 1;
scale_down(ps, 2);
std::cout << area(ps) << std::endl;
if(area(ps) != 225) return 1;
transform(ps, atr);
std::vector<Rectangle> rv;
rv.clear();
ps.get(rv);
if(rv.size() == 1) {
assign(rect, rv.back());
std::cout << rect << std::endl;
}
transform(ps, tr);
rv.clear();
ps.get(rv);
if(rv.size() == 1) {
assign(rect, rv.back());
std::cout << rect << std::endl;
}
}
//test polygon45set transform
pts.clear();
pts.push_back(Point(10, 10));
pts.push_back(Point(15, 10));
pts.push_back(Point(10, 15));
polyHole.set(pts.begin(), pts.end());
Polygon45Set ps451, ps452;
ps451.insert(polyHole);
ps452 = ps451;
std::cout << (ps451 == ps452) << std::endl;
if(ps451 != ps452) return 1;
ps451.transform(atr);
std::cout << (ps451 == ps452) << std::endl;
if(ps451 == ps452) return 1;
ps451.transform(tr);
std::cout << (ps451 == ps452) << std::endl;
if(ps451 != ps452) return 1;
//test polygon45set area
std::cout << area(ps451) << std::endl;
if(area(ps451) != 12.5) return 1;
//test polygon45set scale up down
ps451.scale_up(3);
std::cout << area(ps451) << std::endl;
if(area(ps451) != 112.5) return 1;
ps451.scale_down(2);
std::cout << area(ps451) << std::endl;
if(area(ps451) != 32) return 1;
//test polygonset scalue up down
}
{
std::cout << (testPolygon45SetRect()) << std::endl;
testPolygon45SetPerterbation(); //re-enable after non-intersection fix
testPolygon45Set();
testPolygon45SetDORA(); //re-enable after non-intersection fix
polygon_45_set_data<int> ps45_1, ps45_2, ps45_3;
ps45_1.insert(rectangle_data<int>(0, 0, 10, 10));
ps45_2.insert(rectangle_data<int>(5, 5, 15, 15));
std::vector<polygon_45_data<int> > p45s;
ps45_3 = ps45_1 | ps45_2;
ps45_3.get(p45s);
if(p45s.size()) std::cout << p45s[0] << std::endl;
else {
std::cout << "test failed\n";
return 1;
}
p45s.clear();
ps45_3 = ps45_1 + ps45_2;
ps45_3.get(p45s);
if(p45s.size()) std::cout << p45s[0] << std::endl;
else {
std::cout << "test failed\n";
return 1;
}
p45s.clear();
ps45_3 = ps45_1 * ps45_2;
ps45_3.get(p45s);
if(p45s.size()) std::cout << p45s[0] << std::endl;
else {
std::cout << "test failed\n";
return 1;
}
p45s.clear();
ps45_3 = ps45_1 - ps45_2;
ps45_3.get(p45s);
if(p45s.size()) std::cout << p45s[0] << std::endl;
else {
std::cout << "test failed\n";
return 1;
}
p45s.clear();
ps45_3 = ps45_1 ^ ps45_2;
ps45_3.get(p45s);
if(p45s.size() == 2) std::cout << p45s[0] << " " << p45s[1] << std::endl;
else {
std::cout << "test failed\n";
return 1;
}
std::vector<point_data<int> > pts;
pts.clear();
pts.push_back(point_data<int>(7, 0));
pts.push_back(point_data<int>(20, 13));
pts.push_back(point_data<int>(0, 13));
pts.push_back(point_data<int>(0, 0));
polygon_45_data<int> p45_1(pts.begin(), pts.end());
ps45_3.clear();
ps45_3.insert(p45_1);
p45s.clear();
ps45_3.get(p45s);
if(p45s.size()) std::cout << p45s[0] << std::endl;
else {
std::cout << "test failed\n";
return 1;
}
ps45_3 += 1;
p45s.clear();
ps45_3.get(p45s);
if(p45s.size()) std::cout << p45s[0] << std::endl;
else {
std::cout << "test failed\n";
return 1;
}
ps45_3 -= 1;
p45s.clear();
ps45_3.get(p45s);
if(p45s.size()) std::cout << p45s[0] << std::endl;
else {
std::cout << "test failed\n";
return 1;
}
}
{
polygon_90_set_data<int> p90sd;
p90sd.insert(rectangle_data<int>(0, 0, 10, 10));
std::vector<rectangle_data<int> > rects;
std::vector<polygon_90_data<int> > polys90;
std::vector<polygon_90_with_holes_data<int> > pwhs90;
assign(rects, p90sd);
assign(polys90, p90sd);
assign(pwhs90, p90sd);
std::cout << equivalence(rects, polys90) << std::endl;
std::cout << equivalence(pwhs90, polys90) << std::endl;
pwhs90.clear();
assign(pwhs90, polys90);
std::cout << equivalence(pwhs90, polys90) << std::endl;
}
{
polygon_45_set_data<int> p45sd;
p45sd.insert(rectangle_data<int>(0, 0, 10, 10));
std::vector<rectangle_data<int> > rects;
std::vector<polygon_45_data<int> > polys45;
std::vector<polygon_45_with_holes_data<int> > pwhs45;
get_trapezoids(polys45, p45sd);
assign(polys45, p45sd);
assign(pwhs45, p45sd);
std::cout << equivalence(pwhs45, polys45) << std::endl;
pwhs45.clear();
assign(pwhs45, polys45);
std::cout << equivalence(pwhs45, polys45) << std::endl;
}
{
polygon_set_data<int> psd;
psd.insert(rectangle_data<int>(0, 0, 10, 10));
std::vector<polygon_data<int> > polys;
std::vector<polygon_with_holes_data<int> > pwhs;
assign(polys, psd);
assign(pwhs, psd);
std::cout << equivalence(pwhs, polys) << std::endl;
pwhs.clear();
assign(pwhs, polys);
std::cout << equivalence(pwhs, polys) << std::endl;
}
{
typedef point_3d_data<int> Point3D;
Point3D p3d1(0, 1, 3), p3d2(0, 1, 2);
if(equivalence(p3d1, p3d2)) return 1;
if(euclidean_distance(p3d1, p3d2) != 1) return 1;
if(euclidean_distance(p3d1, p3d2, PROXIMAL) != 1) return 1;
if(manhattan_distance(p3d1, p3d2) != 1) return 1;
assign(p3d1, p3d2);
if(!equivalence(p3d1, p3d2)) return 1;
p3d1 = construct<Point3D>(x(p3d1), y(p3d1), z(p3d1));
if(!equivalence(p3d1, p3d2)) return 1;
convolve(p3d1, p3d2);
if(equivalence(p3d1, p3d2)) return 1;
deconvolve(p3d1, p3d2);
if(!equivalence(p3d1, p3d2)) return 1;
if(get(p3d1, PROXIMAL) != 2) return 1;
scale(p3d1, anisotropic_scale_factor<double>(2, 2, 2));
if(equivalence(p3d1, p3d2)) return 1;
scale_down(p3d1, 2);
if(!equivalence(p3d1, p3d2)) return 1;
scale_up(p3d1, 2);
if(equivalence(p3d1, p3d2)) return 1;
scale_down(p3d1, 2);
set(p3d1, PROXIMAL, 3);
if(equivalence(p3d1, p3d2)) return 1;
axis_transformation atr = axis_transformation::END;
transform(p3d1, atr);
if(z(p3d1) != -3) return 1;
z(p3d1, 2);
if(!equivalence(p3d1, p3d2)) return 1;
}
{
polygon_90_set_data<int> ps1(HORIZONTAL), ps2(VERTICAL);
ps1 += rectangle_data<int>(0, 0, 10, 120);
assign(ps1, ps2);
std::cout << equivalence(ps1, ps2) << std::endl;
}
{
std::vector<rectangle_data<long long> > lobs, input;
input.push_back(rectangle_data<long long>(0, 0, 10, 10));
input.push_back(rectangle_data<long long>(10, 5, 15, 15));
get_max_rectangles(lobs, input);
if(lobs.size() == 3) std::cout << "max rectangles is correct\n";
}
{
polygon_set_data<int> ps1, ps2, ps3;
ps1.insert(rectangle_data<int>(0, 0, 10, 10));
ps2.insert(rectangle_data<int>(0, 0, 15, 5));
ps3.insert(rectangle_data<int>(0, 0, 20, 2));
std::cout << area(ps1 + ps2) << std::endl;
keep(ps1, 0, 100, 0, 100, 0, 100);
if(empty(ps1)) return 1;
rectangle_data<int> bbox;
extents(bbox, ps1);
std::cout << bbox << std::endl;
//resize(ps1, 1);
//shrink(ps1, 1);
//bloat(ps1, 1);
scale_up(ps1, 2);
scale_down(ps1, 2);
axis_transformation atr;
transform(ps1, atr);
std::cout << area(ps1) << std::endl;
if(area(ps1) != 100) return 1;
clear(ps1);
if(!empty(ps1)) return 1;
ps1 = ps2 * ps3;
ps1 *= ps2;
ps1 - ps2;
ps1 -= ps2;
ps1 ^ ps2;
ps1 ^= ps2;
ps1 | ps2;
ps1 |= ps2;
}
{
polygon_45_set_data<int> ps45_1, ps45_2;
ps45_1.insert(rectangle_data<int>(0, 0, 10, 10));
keep(ps45_1, 0, 1000, 0, 1000, 0, 1000);
std::cout << area(ps45_1) << std::endl;
std::cout << empty(ps45_1) << std::endl;
rectangle_data<int> bbox;
extents(bbox, ps45_1);
std::cout << bbox << std::endl;
resize(ps45_1, 1);
shrink(ps45_1, 1);
bloat(ps45_1, 1);
scale_up(ps45_1, 2);
scale_down(ps45_1, 2);
axis_transformation atr;
transform(ps45_1, atr);
std::cout << area(ps45_1) << std::endl;
if(area(ps45_1) != 144) return 1;
clear(ps45_1);
if(!empty(ps45_1)) return 1;
}
{
std::vector<polygon_45_data<int> > p45v;
p45v + p45v;
p45v *= p45v;
p45v += p45v;
p45v - p45v;
p45v -= p45v;
p45v ^ p45v;
p45v ^= p45v;
p45v | p45v;
p45v |= p45v;
p45v + 1;
p45v += 1;
p45v - 1;
p45v -= 1;
p45v + (p45v + p45v);
}
{
polygon_45_set_data<int> ps45;
polygon_90_set_data<int> ps90;
std::vector<polygon_90_with_holes_data<int> > p90whv;
ps45.insert(ps90);
ps45.insert(p90whv);
ps45.insert(p90whv + p90whv);
ps45.insert(polygon_90_with_holes_data<int>());
polygon_with_holes_data<int> pwh;
snap_to_45(pwh);
}
{
point_data<int> pt(1,2);
point_3d_data<int> pt3d(1,2,3);
equivalence(pt, pt3d);
deconvolve(pt, pt3d);
manhattan_distance(pt, pt3d);
move(pt, HORIZONTAL, 1);
scale(pt, anisotropic_scale_factor<double>(2, 2, 2));
pt = pt3d;
}
{
polygon_90_set_data<int> ps90_1, ps90_2;
ps90_1.insert(rectangle_data<int>(0, 0, 10, 10));
keep(ps90_1, 0, 1000, 0, 1000, 0, 1000);
std::cout << area(ps90_1) << std::endl;
std::cout << empty(ps90_1) << std::endl;
rectangle_data<int> bbox;
extents(bbox, ps90_1);
std::cout << bbox << std::endl;
resize(ps90_1, 1);
shrink(ps90_1, 1);
bloat(ps90_1, 1);
scale_up(ps90_1, 2);
scale_down(ps90_1, 2);
scale(ps90_1, anisotropic_scale_factor<double>(2, 2, 2));
scale(ps90_1, anisotropic_scale_factor<double>(0.5, 0.5, 0.5));
axis_transformation atr;
transform(ps90_1, atr);
std::cout << area(ps90_1) << std::endl;
if(area(ps90_1) != 144) return 1;
clear(ps90_1);
if(!empty(ps90_1)) return 1;
}
if(!nonInteger45StessTest()) return 1;
{
using namespace gtl;
typedef polygon_45_property_merge<int, int> p45pm;
p45pm::MergeSetData msd;
polygon_45_set_data<int> ps;
ps += rectangle_data<int>(0, 0, 10, 10);
p45pm::populateMergeSetData(msd, ps.begin(), ps.end(), 444);
ps.clear();
ps += rectangle_data<int>(5, 5, 15, 15);
p45pm::populateMergeSetData(msd, ps.begin(), ps.end(), 333);
std::map<std::set<int>, polygon_45_set_data<int> > result;
p45pm::performMerge(result, msd);
int i = 0;
for(std::map<std::set<int>, polygon_45_set_data<int> >::iterator itr = result.begin();
itr != result.end(); ++itr) {
for(std::set<int>::const_iterator itr2 = (*itr).first.begin();
itr2 != (*itr).first.end(); ++itr2) {
std::cout << *itr2 << " ";
} std::cout << " : ";
std::cout << area((*itr).second) << std::endl;
if(i == 1) {
if(area((*itr).second) != 100) return 1;
} else
if(area((*itr).second) != 300) return 1;
++i;
}
property_merge_45<int, int> pm;
pm.insert(rectangle_data<int>(0, 0, 10, 10), 444);
pm.insert(rectangle_data<int>(5, 5, 15, 15), 333);
std::map<std::set<int>, polygon_45_set_data<int> > mp;
pm.merge(mp);
i = 0;
for(std::map<std::set<int>, polygon_45_set_data<int> >::iterator itr = mp.begin();
itr != mp.end(); ++itr) {
for(std::set<int>::const_iterator itr2 = (*itr).first.begin();
itr2 != (*itr).first.end(); ++itr2) {
std::cout << *itr2 << " ";
} std::cout << " : ";
std::cout << area((*itr).second) << std::endl;
if(i == 1) {
if(area((*itr).second) != 25) return 1;
} else
if(area((*itr).second) != 75) return 1;
++i;
}
std::map<std::vector<int>, polygon_45_set_data<int> > mp2;
pm.merge(mp2);
i = 0;
for(std::map<std::vector<int>, polygon_45_set_data<int> >::iterator itr = mp2.begin();
itr != mp2.end(); ++itr) {
for(std::vector<int>::const_iterator itr2 = (*itr).first.begin();
itr2 != (*itr).first.end(); ++itr2) {
std::cout << *itr2 << " ";
} std::cout << " : ";
std::cout << area((*itr).second) << std::endl;
if(i == 1) {
if(area((*itr).second) != 25) return 1;
} else
if(area((*itr).second) != 75) return 1;
++i;
}
}
{
std::cout << trapezoid_arbitrary_formation<int>::testTrapezoidArbitraryFormationRect(std::cout) << std::endl;
std::cout << trapezoid_arbitrary_formation<int>::testTrapezoidArbitraryFormationP1(std::cout) << std::endl;
std::cout << trapezoid_arbitrary_formation<int>::testTrapezoidArbitraryFormationP2(std::cout) << std::endl;
std::cout << trapezoid_arbitrary_formation<int>::testTrapezoidArbitraryFormationPolys(std::cout) << std::endl;
std::cout << polygon_arbitrary_formation<int>::testPolygonArbitraryFormationSelfTouch1(std::cout) << std::endl;
std::cout << trapezoid_arbitrary_formation<int>::testTrapezoidArbitraryFormationSelfTouch1(std::cout) << std::endl;
typedef rectangle_data<int> Rectangle;
polygon_set_data<int> ps;
ps += Rectangle(0, 1, 10, 11);
ps += Rectangle(5, 6, 15, 16);
std::vector<polygon_data<int> > polys;
ps.get_trapezoids(polys);
for(unsigned int i = 0; i < polys.size(); ++i) {
std::cout << polys[i] << std::endl;
}
ps.transform(axis_transformation(axis_transformation::FLIP_X));
polys.clear();
ps.get_trapezoids(polys);
for(unsigned int i = 0; i < polys.size(); ++i) {
std::cout << polys[i] << std::endl;
}
polys.clear();
ps.get_trapezoids(polys, HORIZONTAL);
for(unsigned int i = 0; i < polys.size(); ++i) {
std::cout << polys[i] << std::endl;
}
}
if(!test_aa_touch()) {
std::cout << "test_aa_touch failed\n";
return 1;
}
if(!test_aa_touch_ur()) {
std::cout << "test_aa_touch_ur failed\n";
return 1;
}
if(!test_aa_touch_ur()) {
std::cout << "test_aa_touch_ur failed\n";
return 1;
}
if(!test_aa_touch_r()) {
std::cout << "test_aa_touch_r failed\n";
return 1;
}
if(!test_aa_touch_boundaries()) {
std::cout << "test_aa_touch_boundaries failed\n";
return 1;
}
if(!test_aa_concept_interact()) {
std::cout << "test_aa_concept_interact failed\n";
return 1;
}
std::cout << "ALL TESTS COMPLETE\n";
return 0;
}