axmol/thirdparty/clipper2/clipper.h

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/*******************************************************************************
* Author : Angus Johnson *
* Version : Clipper2 - ver.1.0.4 *
* Date : 4 August 2022 *
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* Website : http://www.angusj.com *
* Copyright : Angus Johnson 2010-2022 *
* Purpose : This module provides a simple interface to the Clipper Library *
* License : http://www.boost.org/LICENSE_1_0.txt *
*******************************************************************************/
#ifndef CLIPPER_H
#define CLIPPER_H
#include <cstdlib>
#include <vector>
#include "clipper.core.h"
#include "clipper.engine.h"
#include "clipper.offset.h"
#include "clipper.minkowski.h"
namespace Clipper2Lib
{
static const Rect64 MaxInvalidRect64 = Rect64(
(std::numeric_limits<int64_t>::max)(),
(std::numeric_limits<int64_t>::max)(),
(std::numeric_limits<int64_t>::lowest)(),
(std::numeric_limits<int64_t>::lowest)());
static const RectD MaxInvalidRectD = RectD(
(std::numeric_limits<double>::max)(),
(std::numeric_limits<double>::max)(),
(std::numeric_limits<double>::lowest)(),
(std::numeric_limits<double>::lowest)());
inline Paths64 BooleanOp(ClipType cliptype, FillRule fillrule,
const Paths64& subjects, const Paths64& clips)
{
Paths64 result;
Clipper64 clipper;
clipper.AddSubject(subjects);
clipper.AddClip(clips);
clipper.Execute(cliptype, fillrule, result);
return result;
}
inline void BooleanOp(ClipType cliptype, FillRule fillrule,
const Paths64& subjects, const Paths64& clips, PolyTree64& solution)
{
Paths64 sol_open;
Clipper64 clipper;
clipper.AddSubject(subjects);
clipper.AddClip(clips);
clipper.Execute(cliptype, fillrule, solution, sol_open);
}
inline PathsD BooleanOp(ClipType cliptype, FillRule fillrule,
const PathsD& subjects, const PathsD& clips, int decimal_prec = 2)
{
if (decimal_prec > 8 || decimal_prec < -8)
throw Clipper2Exception("invalid decimal precision");
PathsD result;
ClipperD clipper(decimal_prec);
clipper.AddSubject(subjects);
clipper.AddClip(clips);
clipper.Execute(cliptype, fillrule, result);
return result;
}
inline Paths64 Intersect(const Paths64& subjects, const Paths64& clips, FillRule fillrule)
{
return BooleanOp(ClipType::Intersection, fillrule, subjects, clips);
}
inline PathsD Intersect(const PathsD& subjects, const PathsD& clips, FillRule fillrule, int decimal_prec = 2)
{
return BooleanOp(ClipType::Intersection, fillrule, subjects, clips, decimal_prec);
}
inline Paths64 Union(const Paths64& subjects, const Paths64& clips, FillRule fillrule)
{
return BooleanOp(ClipType::Union, fillrule, subjects, clips);
}
inline PathsD Union(const PathsD& subjects, const PathsD& clips, FillRule fillrule, int decimal_prec = 2)
{
return BooleanOp(ClipType::Union, fillrule, subjects, clips, decimal_prec);
}
inline Paths64 Union(const Paths64& subjects, FillRule fillrule)
{
Paths64 result;
Clipper64 clipper;
clipper.AddSubject(subjects);
clipper.Execute(ClipType::Union, fillrule, result);
return result;
}
inline PathsD Union(const PathsD& subjects, FillRule fillrule, int decimal_prec = 2)
{
if (decimal_prec > 8 || decimal_prec < -8)
throw Clipper2Exception("invalid decimal precision");
PathsD result;
ClipperD clipper(decimal_prec);
clipper.AddSubject(subjects);
clipper.Execute(ClipType::Union, fillrule, result);
return result;
}
inline Paths64 Difference(const Paths64& subjects, const Paths64& clips, FillRule fillrule)
{
return BooleanOp(ClipType::Difference, fillrule, subjects, clips);
}
inline PathsD Difference(const PathsD& subjects, const PathsD& clips, FillRule fillrule, int decimal_prec = 2)
{
return BooleanOp(ClipType::Difference, fillrule, subjects, clips, decimal_prec);
}
inline Paths64 Xor(const Paths64& subjects, const Paths64& clips, FillRule fillrule)
{
return BooleanOp(ClipType::Xor, fillrule, subjects, clips);
}
inline PathsD Xor(const PathsD& subjects, const PathsD& clips, FillRule fillrule, int decimal_prec = 2)
{
return BooleanOp(ClipType::Xor, fillrule, subjects, clips, decimal_prec);
}
inline bool IsFullOpenEndType(EndType et)
{
return (et != EndType::Polygon) && (et != EndType::Joined);
}
inline Paths64 InflatePaths(const Paths64& paths, double delta,
JoinType jt, EndType et, double miter_limit = 2.0)
{
ClipperOffset clip_offset(miter_limit);
clip_offset.AddPaths(paths, jt, et);
return clip_offset.Execute(delta);
}
inline PathsD InflatePaths(const PathsD& paths, double delta,
JoinType jt, EndType et, double miter_limit = 2.0, double precision = 2)
{
if (precision < -8 || precision > 8)
throw new Clipper2Exception("Error: Precision exceeds the allowed range.");
const double scale = std::pow(10, precision);
ClipperOffset clip_offset(miter_limit);
clip_offset.AddPaths(ScalePaths<int64_t,double>(paths, scale), jt, et);
Paths64 tmp = clip_offset.Execute(delta * scale);
return ScalePaths<double, int64_t>(tmp, 1 / scale);
}
inline Path64 TranslatePath(const Path64& path, int64_t dx, int64_t dy)
{
Path64 result;
result.reserve(path.size());
for (const Point64& pt : path)
result.push_back(Point64(pt.x + dx, pt.y + dy));
return result;
}
inline PathD TranslatePath(const PathD& path, double dx, double dy)
{
PathD result;
result.reserve(path.size());
for (const PointD& pt : path)
result.push_back(PointD(pt.x + dx, pt.y + dy));
return result;
}
inline Paths64 TranslatePaths(const Paths64& paths, int64_t dx, int64_t dy)
{
Paths64 result;
result.reserve(paths.size());
for (const Path64& path : paths)
result.push_back(TranslatePath(path, dx, dy));
return result;
}
inline PathsD TranslatePaths(const PathsD& paths, double dx, double dy)
{
PathsD result;
result.reserve(paths.size());
for (const PathD& path : paths)
result.push_back(TranslatePath(path, dx, dy));
return result;
}
inline Rect64 Bounds(const Path64& path)
{
Rect64 rec = MaxInvalidRect64;
for (const Point64& pt : path)
{
if (pt.x < rec.left) rec.left = pt.x;
if (pt.x > rec.right) rec.right = pt.x;
if (pt.y < rec.top) rec.top = pt.y;
if (pt.y > rec.bottom) rec.bottom = pt.y;
}
if (rec.IsEmpty()) return Rect64();
return rec;
}
inline Rect64 Bounds(const Paths64& paths)
{
Rect64 rec = MaxInvalidRect64;
for (const Path64& path : paths)
for (const Point64& pt : path)
{
if (pt.x < rec.left) rec.left = pt.x;
if (pt.x > rec.right) rec.right = pt.x;
if (pt.y < rec.top) rec.top = pt.y;
if (pt.y > rec.bottom) rec.bottom = pt.y;
}
if (rec.IsEmpty()) return Rect64();
return rec;
}
inline RectD Bounds(const PathD& path)
{
RectD rec = MaxInvalidRectD;
for (const PointD& pt : path)
{
if (pt.x < rec.left) rec.left = pt.x;
if (pt.x > rec.right) rec.right = pt.x;
if (pt.y < rec.top) rec.top = pt.y;
if (pt.y > rec.bottom) rec.bottom = pt.y;
}
if (rec.IsEmpty()) return RectD();
return rec;
}
inline RectD Bounds(const PathsD& paths)
{
RectD rec = MaxInvalidRectD;
for (const PathD& path : paths)
for (const PointD& pt : path)
{
if (pt.x < rec.left) rec.left = pt.x;
if (pt.x > rec.right) rec.right = pt.x;
if (pt.y < rec.top) rec.top = pt.y;
if (pt.y > rec.bottom) rec.bottom = pt.y;
}
if (rec.IsEmpty()) return RectD();
return rec;
}
namespace details
{
template <typename T>
inline void InternalPolyNodeToPaths(const PolyPath<T>& polypath, Paths<T>& paths)
{
paths.push_back(polypath.Polygon());
for (auto child : polypath)
InternalPolyNodeToPaths(*child, paths);
}
inline bool InternalPolyPathContainsChildren(const PolyPath64& pp)
{
for (auto child : pp)
{
for (const Point64& pt : child->Polygon())
if (PointInPolygon(pt, pp.Polygon()) == PointInPolygonResult::IsOutside)
return false;
if (child->Count() > 0 && !InternalPolyPathContainsChildren(*child))
return false;
}
return true;
}
inline bool GetInt(std::string::const_iterator& iter, const
std::string::const_iterator& end_iter, int64_t& val)
{
val = 0;
bool is_neg = *iter == '-';
if (is_neg) ++iter;
std::string::const_iterator start_iter = iter;
while (iter != end_iter &&
((*iter >= '0') && (*iter <= '9')))
{
val = val * 10 + (static_cast<int64_t>(*iter++) - '0');
}
if (is_neg) val = -val;
return (iter != start_iter);
}
inline bool GetFloat(std::string::const_iterator& iter, const
std::string::const_iterator& end_iter, double& val)
{
val = 0;
bool is_neg = *iter == '-';
if (is_neg) ++iter;
int dec_pos = -1;
std::string::const_iterator start_iter = iter;
while (iter != end_iter && (*iter == '.' ||
((*iter >= '0') && (*iter <= '9'))))
{
if (*iter == '.')
{
if (dec_pos >= 0) return false;
dec_pos = 0;
++iter;
continue;
}
if (dec_pos >= 0) dec_pos++;
val = val * 10 + ((int64_t)(*iter++) - '0');
}
if (iter == start_iter || dec_pos == 0) return false;
if (dec_pos > 0)
val *= std::pow(10, -dec_pos);
if (is_neg)
val *= -1;
return true;
}
inline void SkipWhiteSpace(std::string::const_iterator& iter,
const std::string::const_iterator& end_iter)
{
while (iter != end_iter && *iter <= ' ') ++iter;
}
inline void SkipSpacesWithOptionalComma(std::string::const_iterator& iter,
const std::string::const_iterator& end_iter)
{
bool comma_seen = false;
while (iter != end_iter)
{
if (*iter == ' ') ++iter;
else if (*iter == ',')
{
if (comma_seen) return; // don't skip 2 commas!
comma_seen = true;
++iter;
}
else return;
}
}
inline bool has_one_match(const char c, char* chrs)
{
while (*chrs > 0 && c != *chrs) ++chrs;
if (!*chrs) return false;
*chrs = ' '; // only match once per char
return true;
}
inline void SkipUserDefinedChars(std::string::const_iterator& iter,
const std::string::const_iterator& end_iter, const std::string& skip_chars)
{
const size_t MAX_CHARS = 16;
char buff[MAX_CHARS] = {0};
std::copy(skip_chars.cbegin(), skip_chars.cend(), &buff[0]);
while (iter != end_iter &&
(*iter <= ' ' || has_one_match(*iter, buff))) ++iter;
return;
}
} // end details namespace
template <typename T>
inline Paths<T> PolyTreeToPaths(const PolyTree<T>& polytree)
{
Paths<T> result;
for (auto child : polytree)
details::InternalPolyNodeToPaths(*child, result);
return result;
}
inline bool CheckPolytreeFullyContainsChildren(const PolyTree64& polytree)
{
for (auto child : polytree)
if (child->Count() > 0 && !details::InternalPolyPathContainsChildren(*child))
return false;
return true;
}
inline Path64 MakePath(const std::string& s)
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{
const std::string skip_chars = " ,(){}[]";
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Path64 result;
std::string::const_iterator s_iter = s.cbegin();
details::SkipUserDefinedChars(s_iter, s.cend(), skip_chars);
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while (s_iter != s.cend())
{
int64_t y = 0, x = 0;
if (!details::GetInt(s_iter, s.cend(), x)) break;
details::SkipSpacesWithOptionalComma(s_iter, s.cend());
if (!details::GetInt(s_iter, s.cend(), y)) break;
result.push_back(Point64(x, y));
details::SkipUserDefinedChars(s_iter, s.cend(), skip_chars);
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}
return result;
}
inline PathD MakePathD(const std::string& s)
{
const std::string skip_chars = " ,(){}[]";
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PathD result;
std::string::const_iterator s_iter = s.cbegin();
details::SkipUserDefinedChars(s_iter, s.cend(), skip_chars);
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while (s_iter != s.cend())
{
double y = 0, x = 0;
if (!details::GetFloat(s_iter, s.cend(), x)) break;
details::SkipSpacesWithOptionalComma(s_iter, s.cend());
if (!details::GetFloat(s_iter, s.cend(), y)) break;
result.push_back(PointD(x, y));
details::SkipUserDefinedChars(s_iter, s.cend(), skip_chars);
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}
return result;
}
inline Path64 TrimCollinear(const Path64& p, bool is_open_path = false)
{
size_t len = p.size();
if (len < 3)
{
if (!is_open_path || len < 2 || p[0] == p[1]) return Path64();
else return p;
}
Path64 dst;
dst.reserve(len);
Path64::const_iterator srcIt = p.cbegin(), prevIt, stop = p.cend() - 1;
if (!is_open_path)
{
while (srcIt != stop && !CrossProduct(*stop, *srcIt, *(srcIt + 1)))
++srcIt;
while (srcIt != stop && !CrossProduct(*(stop - 1), *stop, *srcIt))
--stop;
if (srcIt == stop) return Path64();
}
prevIt = srcIt++;
dst.push_back(*prevIt);
for (; srcIt != stop; ++srcIt)
{
if (CrossProduct(*prevIt, *srcIt, *(srcIt + 1)))
{
prevIt = srcIt;
dst.push_back(*prevIt);
}
}
if (is_open_path)
dst.push_back(*srcIt);
else if (CrossProduct(*prevIt, *stop, dst[0]))
dst.push_back(*stop);
else
{
while (dst.size() > 2 &&
!CrossProduct(dst.end()[-1], dst.end()[-2], dst[0]))
dst.pop_back();
if (dst.size() < 3) return Path64();
}
return dst;
}
inline PathD TrimCollinear(const PathD& path, int precision, bool is_open_path = false)
{
if (precision > 8 || precision < -8)
throw new Clipper2Exception("Error: Precision exceeds the allowed range.");
const double scale = std::pow(10, precision);
Path64 p = ScalePath<int64_t, double>(path, scale);
p = TrimCollinear(p, is_open_path);
return ScalePath<double, int64_t>(p, 1/scale);
}
template <typename T>
inline double Distance(const Point<T> pt1, const Point<T> pt2)
{
return std::sqrt(DistanceSqr(pt1, pt2));
}
template <typename T>
inline double Length(const Path<T>& path, bool is_closed_path = false)
{
double result = 0.0;
if (path.size() < 2) return result;
auto it = path.cbegin(), stop = path.end() - 1;
for (; it != stop; ++it)
result += Distance(*it, *(it + 1));
if (is_closed_path)
result += Distance(*stop, *path.cbegin());
return result;
}
template <typename T>
inline bool NearCollinear(const Point<T>& pt1, const Point<T>& pt2, const Point<T>& pt3, double sin_sqrd_min_angle_rads)
{
double cp = std::abs(CrossProduct(pt1, pt2, pt3));
return (cp * cp) / (DistanceSqr(pt1, pt2) * DistanceSqr(pt2, pt3)) < sin_sqrd_min_angle_rads;
}
template <typename T>
inline Path<T> Ellipse(const Rect<T>& rect, int steps = 0)
{
return Ellipse(rect.MidPoint(),
static_cast<double>(rect.Width()) *0.5,
static_cast<double>(rect.Height()) * 0.5, steps);
}
template <typename T>
inline Path<T> Ellipse(const Point<T>& center,
double radiusX, double radiusY = 0, int steps = 0)
{
if (radiusX <= 0) return Path<T>();
if (radiusY <= 0) radiusY = radiusX;
if (steps <= 2)
steps = static_cast<int>(PI * sqrt((radiusX + radiusY) / 2));
double si = std::sin(2 * PI / steps);
double co = std::cos(2 * PI / steps);
double dx = co, dy = si;
Path<T> result;
result.reserve(steps);
result.push_back(Point<T>(center.x + radiusX, static_cast<double>(center.y)));
for (int i = 1; i < steps; ++i)
{
result.push_back(Point<T>(center.x + radiusX * dx, center.y + radiusY * dy));
double x = dx * co - dy * si;
dy = dy * co + dx * si;
dx = x;
}
return result;
}
template <typename T>
inline double PerpendicDistFromLineSqrd(const Point<T>& pt,
const Point<T>& line1, const Point<T>& line2)
{
double a = static_cast<double>(pt.x - line1.x);
double b = static_cast<double>(pt.y - line1.y);
double c = static_cast<double>(line2.x - line1.x);
double d = static_cast<double>(line2.y - line1.y);
if (c == 0 && d == 0) return 0;
return Sqr(a * d - c * b) / (c * c + d * d);
}
template <typename T>
inline void RDP(const Path<T> path, std::size_t begin,
std::size_t end, double epsSqrd, std::vector<bool>& flags)
{
typename Path<T>::size_type idx = 0;
double max_d = 0;
while (end > begin && path[begin] == path[end]) flags[end--] = false;
for (typename Path<T>::size_type i = begin + 1; i < end; ++i)
{
// PerpendicDistFromLineSqrd - avoids expensive Sqrt()
double d = PerpendicDistFromLineSqrd(path[i], path[begin], path[end]);
if (d <= max_d) continue;
max_d = d;
idx = i;
}
if (max_d <= epsSqrd) return;
flags[idx] = true;
if (idx > begin + 1) RDP(path, begin, idx, epsSqrd, flags);
if (idx < end - 1) RDP(path, idx, end, epsSqrd, flags);
}
template <typename T>
inline Path<T> RamerDouglasPeucker(const Path<T>& path, double epsilon)
{
const typename Path<T>::size_type len = path.size();
if (len < 5) return Path<T>(path);
std::vector<bool> flags(len);
flags[0] = true;
flags[len - 1] = true;
RDP(path, 0, len - 1, Sqr(epsilon), flags);
Path<T> result;
result.reserve(len);
for (typename Path<T>::size_type i = 0; i < len; ++i)
if (flags[i])
result.push_back(path[i]);
return result;
}
template <typename T>
inline Paths<T> RamerDouglasPeucker(const Paths<T>& paths, double epsilon)
{
Paths<T> result;
result.reserve(paths.size());
for (const Path<T>& path : paths)
result.push_back(RamerDouglasPeucker<T>(path, epsilon));
return result;
}
} // end Clipper2Lib namespace
#endif // CLIPPER_H