Merge pull request #22 from pierre-dejoue/master

Add documentation and code patches for maintenability
This commit is contained in:
Jan Niklas Hasse 2020-10-26 20:18:51 +00:00 committed by GitHub
commit e9938d9c68
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10 changed files with 116 additions and 65 deletions

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@ -7,7 +7,8 @@ option(P2T_BUILD_TESTS "Build tests" OFF)
option(P2T_BUILD_TESTBED "Build the testbed application" OFF)
file(GLOB SOURCES poly2tri/common/*.cc poly2tri/sweep/*.cc)
add_library(poly2tri ${SOURCES})
file(GLOB HEADERS poly2tri/*.h poly2tri/common/*.h poly2tri/sweep/*.h)
add_library(poly2tri ${SOURCES} ${HEADERS})
target_include_directories(poly2tri INTERFACE ${CMAKE_CURRENT_SOURCE_DIR})
if(P2T_BUILD_TESTS)

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@ -52,6 +52,8 @@ python waf configure
python waf build
```
Alternatively, the testbed can be built using cmake. See below.
Running the Examples
--------------------
@ -59,7 +61,7 @@ Load data points from a file:
```
p2t <filename> <center_x> <center_y> <zoom>
```
Random distribution of points inside a consrained box:
Random distribution of points inside a constrained box:
```
p2t random <num_points> <box_radius> <zoom>
```
@ -71,3 +73,42 @@ Examples:
./build/p2t random 10 100 5.0
./build/p2t random 1000 20000 0.025
```
BUILD WITH CMAKE
================
Build the library
-----------------
```
mkdir build && cd build
cmake -GNinja
cmake --build .
```
Build and run the unit tests
----------------------------
```
mkdir build && cd build
cmake -GNinja -DP2T_BUILD_TESTS=ON
cmake --build .
ctest --output-on-failure
```
Build the testbed
-----------------
```
mkdir build && cd build
cmake -GNinja -DP2T_BUILD_TESTBED=ON
cmake --build .
```
References
==========
- Domiter V. and Zalik B. (2008) Sweepline algorithm for constrained Delaunay triangulation
- FlipScan by library author Thomas Åhlén
![FlipScan](doc/FlipScan.png)

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@ -243,6 +243,17 @@ Point* Triangle::PointCCW(const Point& point)
return nullptr;
}
// The neighbor across to given point
Triangle* Triangle::NeighborAcross(const Point& point)
{
if (&point == points_[0]) {
return neighbors_[0];
} else if (&point == points_[1]) {
return neighbors_[1];
}
return neighbors_[2];
}
// The neighbor clockwise to given point
Triangle* Triangle::NeighborCW(const Point& point)
{
@ -349,23 +360,6 @@ void Triangle::SetDelunayEdgeCW(const Point& p, bool e)
}
}
// The neighbor across to given point
Triangle& Triangle::NeighborAcross(const Point& opoint)
{
Triangle* neighbor = nullptr;
if (&opoint == points_[0]) {
neighbor = neighbors_[0];
} else if (&opoint == points_[1]) {
neighbor = neighbors_[1];
} else {
neighbor = neighbors_[2];
}
if (neighbor == nullptr) {
throw std::runtime_error("NeighborAcross - null neighbor");
}
return *neighbor;
}
void Triangle::DebugPrint()
{
std::cout << *points_[0] << " " << *points_[1] << " " << *points_[2] << std::endl;

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@ -176,6 +176,7 @@ void MarkConstrainedEdge(Point* p, Point* q);
int Index(const Point* p);
int EdgeIndex(const Point* p1, const Point* p2);
Triangle* NeighborAcross(const Point& point);
Triangle* NeighborCW(const Point& point);
Triangle* NeighborCCW(const Point& point);
bool GetConstrainedEdgeCCW(const Point& p);
@ -203,8 +204,6 @@ void ClearDelunayEdges();
inline bool IsInterior();
inline void IsInterior(bool b);
Triangle& NeighborAcross(const Point& opoint);
void DebugPrint();
bool CircumcicleContains(const Point&) const;

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@ -108,6 +108,9 @@ void Sweep::EdgeEvent(SweepContext& tcx, Edge* edge, Node* node)
void Sweep::EdgeEvent(SweepContext& tcx, Point& ep, Point& eq, Triangle* triangle, Point& point)
{
if (triangle == nullptr) {
throw std::runtime_error("EdgeEvent - null triangle");
}
if (IsEdgeSideOfTriangle(*triangle, ep, eq)) {
return;
}
@ -115,13 +118,13 @@ void Sweep::EdgeEvent(SweepContext& tcx, Point& ep, Point& eq, Triangle* triangl
Point* p1 = triangle->PointCCW(point);
Orientation o1 = Orient2d(eq, *p1, ep);
if (o1 == COLLINEAR) {
if( triangle->Contains(&eq, p1)) {
triangle->MarkConstrainedEdge(&eq, p1 );
if (triangle->Contains(&eq, p1)) {
triangle->MarkConstrainedEdge(&eq, p1);
// We are modifying the constraint maybe it would be better to
// not change the given constraint and just keep a variable for the new constraint
tcx.edge_event.constrained_edge->q = p1;
triangle = &triangle->NeighborAcross(point);
EdgeEvent( tcx, ep, *p1, triangle, *p1 );
triangle = triangle->NeighborAcross(point);
EdgeEvent(tcx, ep, *p1, triangle, *p1);
} else {
throw std::runtime_error("EdgeEvent - collinear points not supported");
}
@ -131,13 +134,13 @@ void Sweep::EdgeEvent(SweepContext& tcx, Point& ep, Point& eq, Triangle* triangl
Point* p2 = triangle->PointCW(point);
Orientation o2 = Orient2d(eq, *p2, ep);
if (o2 == COLLINEAR) {
if( triangle->Contains(&eq, p2)) {
triangle->MarkConstrainedEdge(&eq, p2 );
if (triangle->Contains(&eq, p2)) {
triangle->MarkConstrainedEdge(&eq, p2);
// We are modifying the constraint maybe it would be better to
// not change the given constraint and just keep a variable for the new constraint
tcx.edge_event.constrained_edge->q = p2;
triangle = &triangle->NeighborAcross(point);
EdgeEvent( tcx, ep, *p2, triangle, *p2 );
triangle = triangle->NeighborAcross(point);
EdgeEvent(tcx, ep, *p2, triangle, *p2);
} else {
throw std::runtime_error("EdgeEvent - collinear points not supported");
}
@ -149,12 +152,13 @@ void Sweep::EdgeEvent(SweepContext& tcx, Point& ep, Point& eq, Triangle* triangl
// that will cross edge
if (o1 == CW) {
triangle = triangle->NeighborCCW(point);
} else{
} else {
triangle = triangle->NeighborCW(point);
}
EdgeEvent(tcx, ep, eq, triangle, point);
} else {
// This triangle crosses constraint so lets flippin start!
assert(triangle);
FlipEdgeEvent(tcx, ep, eq, triangle, point);
}
}
@ -215,7 +219,6 @@ void Sweep::Fill(SweepContext& tcx, Node& node)
if (!Legalize(tcx, *triangle)) {
tcx.MapTriangleToNodes(*triangle);
}
}
void Sweep::FillAdvancingFront(SweepContext& tcx, Node& n)
@ -293,7 +296,7 @@ double Sweep::Angle(const Point* origin, const Point* pa, const Point* pb) const
*/
const double px = origin->x;
const double py = origin->y;
const double ax = pa->x- px;
const double ax = pa->x - px;
const double ay = pa->y - py;
const double bx = pb->x - px;
const double by = pb->y - py;
@ -586,7 +589,7 @@ void Sweep::FillRightBelowEdgeEvent(SweepContext& tcx, Edge* edge, Node& node)
if (Orient2d(*node.point, *node.next->point, *node.next->next->point) == CCW) {
// Concave
FillRightConcaveEdgeEvent(tcx, edge, node);
} else{
} else {
// Convex
FillRightConvexEdgeEvent(tcx, edge, node);
// Retry this one
@ -610,7 +613,6 @@ void Sweep::FillRightConcaveEdgeEvent(SweepContext& tcx, Edge* edge, Node& node)
}
}
}
}
void Sweep::FillRightConvexEdgeEvent(SweepContext& tcx, Edge* edge, Node& node)
@ -619,13 +621,13 @@ void Sweep::FillRightConvexEdgeEvent(SweepContext& tcx, Edge* edge, Node& node)
if (Orient2d(*node.next->point, *node.next->next->point, *node.next->next->next->point) == CCW) {
// Concave
FillRightConcaveEdgeEvent(tcx, edge, *node.next);
} else{
} else {
// Convex
// Next above or below edge?
if (Orient2d(*edge->q, *node.next->next->point, *edge->p) == CCW) {
// Below
FillRightConvexEdgeEvent(tcx, edge, *node.next);
} else{
} else {
// Above
}
}
@ -664,13 +666,13 @@ void Sweep::FillLeftConvexEdgeEvent(SweepContext& tcx, Edge* edge, Node& node)
if (Orient2d(*node.prev->point, *node.prev->prev->point, *node.prev->prev->prev->point) == CW) {
// Concave
FillLeftConcaveEdgeEvent(tcx, edge, *node.prev);
} else{
} else {
// Convex
// Next above or below edge?
if (Orient2d(*edge->q, *node.prev->prev->point, *edge->p) == CW) {
// Below
FillLeftConvexEdgeEvent(tcx, edge, *node.prev);
} else{
} else {
// Above
}
}
@ -686,17 +688,22 @@ void Sweep::FillLeftConcaveEdgeEvent(SweepContext& tcx, Edge* edge, Node& node)
if (Orient2d(*node.point, *node.prev->point, *node.prev->prev->point) == CW) {
// Next is concave
FillLeftConcaveEdgeEvent(tcx, edge, node);
} else{
} else {
// Next is convex
}
}
}
}
void Sweep::FlipEdgeEvent(SweepContext& tcx, Point& ep, Point& eq, Triangle* t, Point& p)
{
Triangle& ot = t->NeighborAcross(p);
assert(t);
Triangle* ot_ptr = t->NeighborAcross(p);
if (ot_ptr == nullptr)
{
throw std::runtime_error("FlipEdgeEvent - null neighbor across");
}
Triangle& ot = *ot_ptr;
Point& op = *ot.OppositePoint(*t, p);
if (InScanArea(p, *t->PointCCW(p), *t->PointCW(p), op)) {
@ -762,7 +769,11 @@ Point& Sweep::NextFlipPoint(Point& ep, Point& eq, Triangle& ot, Point& op)
void Sweep::FlipScanEdgeEvent(SweepContext& tcx, Point& ep, Point& eq, Triangle& flip_triangle,
Triangle& t, Point& p)
{
Triangle& ot = t.NeighborAcross(p);
Triangle* ot_ptr = t.NeighborAcross(p);
if (ot_ptr == nullptr) {
throw std::runtime_error("FlipScanEdgeEvent - null neighbor across");
}
Triangle& ot = *ot_ptr;
Point& op = *ot.OppositePoint(t, p);
if (InScanArea(eq, *flip_triangle.PointCCW(eq), *flip_triangle.PointCW(eq), op)) {
@ -775,7 +786,7 @@ void Sweep::FlipScanEdgeEvent(SweepContext& tcx, Point& ep, Point& eq, Triangle&
// also need to set a new flip_triangle first
// Turns out at first glance that this is somewhat complicated
// so it will have to wait.
} else{
} else {
Point& newP = NextFlipPoint(ep, eq, ot, op);
FlipScanEdgeEvent(tcx, ep, eq, flip_triangle, ot, newP);
}
@ -790,5 +801,4 @@ Sweep::~Sweep() {
}
}
} // namespace p2t

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@ -33,7 +33,7 @@
* Zalik, B.(2008)'Sweep-line algorithm for constrained Delaunay triangulation',
* International Journal of Geographical Information Science
*
* "FlipScan" Constrained Edge Algorithm invented by Thomas ?hl?n, thahlen@gmail.com
* "FlipScan" Constrained Edge Algorithm invented by Thomas Åhlén, thahlen@gmail.com
*/
#ifndef SWEEP_H

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@ -87,8 +87,8 @@ void SweepContext::InitTriangulation()
double dx = kAlpha * (xmax - xmin);
double dy = kAlpha * (ymax - ymin);
head_ = new Point(xmax + dx, ymin - dy);
tail_ = new Point(xmin - dx, ymin - dy);
head_ = new Point(xmin - dx, ymin - dy);
tail_ = new Point(xmax + dx, ymin - dy);
// Sort points along y-axis
std::sort(points_.begin(), points_.end(), cmp);
@ -124,7 +124,7 @@ void SweepContext::CreateAdvancingFront()
{
// Initial triangle
Triangle* triangle = new Triangle(*points_[0], *tail_, *head_);
Triangle* triangle = new Triangle(*points_[0], *head_, *tail_);
map_.push_back(triangle);

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@ -28,18 +28,22 @@
* NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include <cstdlib>
#include <GLFW/glfw3.h>
#include <time.h>
#include <fstream>
#include <string>
#include <sstream>
#include <algorithm>
#include <iterator>
#include <iostream>
using namespace std;
#include <poly2tri/poly2tri.h>
#include "../poly2tri/poly2tri.h"
#include <GLFW/glfw3.h>
#include <algorithm>
#include <cstdlib>
#include <ctime>
#include <fstream>
#include <iostream>
#include <iterator>
#include <list>
#include <sstream>
#include <string>
#include <vector>
using namespace std;
using namespace p2t;
void Init();

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@ -3,9 +3,11 @@
#endif
#define BOOST_TEST_MODULE Poly2triTest
#include <poly2tri/poly2tri.h>
#include <boost/filesystem/path.hpp>
#include <boost/test/unit_test.hpp>
#include <poly2tri/poly2tri.h>
#include <fstream>
#include <iostream>
#include <iterator>
@ -19,7 +21,7 @@ BOOST_AUTO_TEST_CASE(BasicTest)
new p2t::Point(1, 1),
};
p2t::CDT cdt{ polyline };
cdt.Triangulate();
BOOST_CHECK_NO_THROW(cdt.Triangulate());
const auto result = cdt.GetTriangles();
BOOST_REQUIRE_EQUAL(result.size(), 1);
BOOST_CHECK_EQUAL(*result[0]->GetPoint(0), *polyline[0]);
@ -36,7 +38,7 @@ BOOST_AUTO_TEST_CASE(QuadTest)
std::vector<p2t::Point*> polyline{ new p2t::Point(0, 0), new p2t::Point(0, 1),
new p2t::Point(1, 1), new p2t::Point(1, 0) };
p2t::CDT cdt{ polyline };
cdt.Triangulate();
BOOST_CHECK_NO_THROW(cdt.Triangulate());
const auto result = cdt.GetTriangles();
BOOST_REQUIRE_EQUAL(result.size(), 2);
BOOST_CHECK(p2t::IsDelaunay(result));
@ -45,7 +47,7 @@ BOOST_AUTO_TEST_CASE(QuadTest)
}
}
BOOST_AUTO_TEST_CASE(QuadTestThrow)
BOOST_AUTO_TEST_CASE(NarrowQuadTest)
{
// Very narrow quad that demonstrates a failure case during triangulation
std::vector<p2t::Point*> polyline {
@ -90,7 +92,7 @@ BOOST_AUTO_TEST_CASE(TestbedFilesTest)
polyline.push_back(new p2t::Point(x, y));
}
p2t::CDT cdt{ polyline };
cdt.Triangulate();
BOOST_CHECK_NO_THROW(cdt.Triangulate());
const auto result = cdt.GetTriangles();
BOOST_REQUIRE(result.size() * 3 > polyline.size());
BOOST_CHECK_MESSAGE(p2t::IsDelaunay(result), filename + std::to_string(polyline.size()));