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|
// SPDX-License-Identifier: GPL-2.0-or-later
/*
* Specific geometry functions for Inkscape, not provided my lib2geom.
*
* Author:
* Johan Engelen <goejendaagh@zonnet.nl>
*
* Copyright (C) 2008 Johan Engelen
*
* Released under GNU GPL v2+, read the file 'COPYING' for more information.
*/
#include <algorithm>
#include "helper/geom.h"
#include "helper/geom-curves.h"
#include <2geom/curves.h>
#include <2geom/sbasis-to-bezier.h>
using Geom::X;
using Geom::Y;
//#################################################################################
// BOUNDING BOX CALCULATIONS
/* Fast bbox calculation */
/* Thanks to Nathan Hurst for suggesting it */
static void
cubic_bbox (Geom::Coord x000, Geom::Coord y000, Geom::Coord x001, Geom::Coord y001, Geom::Coord x011, Geom::Coord y011, Geom::Coord x111, Geom::Coord y111, Geom::Rect &bbox)
{
Geom::Coord a, b, c, D;
bbox[0].expandTo(x111);
bbox[1].expandTo(y111);
// It already contains (x000,y000) and (x111,y111)
// All points of the Bezier lie in the convex hull of (x000,y000), (x001,y001), (x011,y011) and (x111,y111)
// So, if it also contains (x001,y001) and (x011,y011) we don't have to compute anything else!
// Note that we compute it for the X and Y range separately to make it easier to use them below
bool containsXrange = bbox[0].contains(x001) && bbox[0].contains(x011);
bool containsYrange = bbox[1].contains(y001) && bbox[1].contains(y011);
/*
* xttt = s * (s * (s * x000 + t * x001) + t * (s * x001 + t * x011)) + t * (s * (s * x001 + t * x011) + t * (s * x011 + t * x111))
* xttt = s * (s2 * x000 + s * t * x001 + t * s * x001 + t2 * x011) + t * (s2 * x001 + s * t * x011 + t * s * x011 + t2 * x111)
* xttt = s * (s2 * x000 + 2 * st * x001 + t2 * x011) + t * (s2 * x001 + 2 * st * x011 + t2 * x111)
* xttt = s3 * x000 + 2 * s2t * x001 + st2 * x011 + s2t * x001 + 2st2 * x011 + t3 * x111
* xttt = s3 * x000 + 3s2t * x001 + 3st2 * x011 + t3 * x111
* xttt = s3 * x000 + (1 - s) 3s2 * x001 + (1 - s) * (1 - s) * 3s * x011 + (1 - s) * (1 - s) * (1 - s) * x111
* xttt = s3 * x000 + (3s2 - 3s3) * x001 + (3s - 6s2 + 3s3) * x011 + (1 - 2s + s2 - s + 2s2 - s3) * x111
* xttt = (x000 - 3 * x001 + 3 * x011 - x111) * s3 +
* ( 3 * x001 - 6 * x011 + 3 * x111) * s2 +
* ( 3 * x011 - 3 * x111) * s +
* ( x111)
* xttt' = (3 * x000 - 9 * x001 + 9 * x011 - 3 * x111) * s2 +
* ( 6 * x001 - 12 * x011 + 6 * x111) * s +
* ( 3 * x011 - 3 * x111)
*/
if (!containsXrange) {
a = 3 * x000 - 9 * x001 + 9 * x011 - 3 * x111;
b = 6 * x001 - 12 * x011 + 6 * x111;
c = 3 * x011 - 3 * x111;
/*
* s = (-b +/- sqrt (b * b - 4 * a * c)) / 2 * a;
*/
if (fabs (a) < Geom::EPSILON) {
/* s = -c / b */
if (fabs (b) > Geom::EPSILON) {
double s;
s = -c / b;
if ((s > 0.0) && (s < 1.0)) {
double t = 1.0 - s;
double xttt = s * s * s * x000 + 3 * s * s * t * x001 + 3 * s * t * t * x011 + t * t * t * x111;
bbox[0].expandTo(xttt);
}
}
} else {
/* s = (-b +/- sqrt (b * b - 4 * a * c)) / 2 * a; */
D = b * b - 4 * a * c;
if (D >= 0.0) {
Geom::Coord d, s, t, xttt;
/* Have solution */
d = sqrt (D);
s = (-b + d) / (2 * a);
if ((s > 0.0) && (s < 1.0)) {
t = 1.0 - s;
xttt = s * s * s * x000 + 3 * s * s * t * x001 + 3 * s * t * t * x011 + t * t * t * x111;
bbox[0].expandTo(xttt);
}
s = (-b - d) / (2 * a);
if ((s > 0.0) && (s < 1.0)) {
t = 1.0 - s;
xttt = s * s * s * x000 + 3 * s * s * t * x001 + 3 * s * t * t * x011 + t * t * t * x111;
bbox[0].expandTo(xttt);
}
}
}
}
if (!containsYrange) {
a = 3 * y000 - 9 * y001 + 9 * y011 - 3 * y111;
b = 6 * y001 - 12 * y011 + 6 * y111;
c = 3 * y011 - 3 * y111;
if (fabs (a) < Geom::EPSILON) {
/* s = -c / b */
if (fabs (b) > Geom::EPSILON) {
double s;
s = -c / b;
if ((s > 0.0) && (s < 1.0)) {
double t = 1.0 - s;
double yttt = s * s * s * y000 + 3 * s * s * t * y001 + 3 * s * t * t * y011 + t * t * t * y111;
bbox[1].expandTo(yttt);
}
}
} else {
/* s = (-b +/- sqrt (b * b - 4 * a * c)) / 2 * a; */
D = b * b - 4 * a * c;
if (D >= 0.0) {
Geom::Coord d, s, t, yttt;
/* Have solution */
d = sqrt (D);
s = (-b + d) / (2 * a);
if ((s > 0.0) && (s < 1.0)) {
t = 1.0 - s;
yttt = s * s * s * y000 + 3 * s * s * t * y001 + 3 * s * t * t * y011 + t * t * t * y111;
bbox[1].expandTo(yttt);
}
s = (-b - d) / (2 * a);
if ((s > 0.0) && (s < 1.0)) {
t = 1.0 - s;
yttt = s * s * s * y000 + 3 * s * s * t * y001 + 3 * s * t * t * y011 + t * t * t * y111;
bbox[1].expandTo(yttt);
}
}
}
}
}
Geom::OptRect
bounds_fast_transformed(Geom::PathVector const & pv, Geom::Affine const & t)
{
return bounds_exact_transformed(pv, t); //use this as it is faster for now! :)
// return Geom::bounds_fast(pv * t);
}
Geom::OptRect
bounds_exact_transformed(Geom::PathVector const & pv, Geom::Affine const & t)
{
if (pv.empty())
return Geom::OptRect();
Geom::Point initial = pv.front().initialPoint() * t;
Geom::Rect bbox(initial, initial); // obtain well defined bbox as starting point to unionWith
for (const auto & it : pv) {
bbox.expandTo(it.initialPoint() * t);
// don't loop including closing segment, since that segment can never increase the bbox
for (Geom::Path::const_iterator cit = it.begin(); cit != it.end_open(); ++cit) {
Geom::Curve const &c = *cit;
unsigned order = 0;
if (Geom::BezierCurve const* b = dynamic_cast<Geom::BezierCurve const*>(&c)) {
order = b->order();
}
if (order == 1) { // line segment
bbox.expandTo(c.finalPoint() * t);
// TODO: we can make the case for quadratics faster by degree elevating them to
// cubic and then taking the bbox of that.
} else if (order == 3) { // cubic bezier
Geom::CubicBezier const &cubic_bezier = static_cast<Geom::CubicBezier const&>(c);
Geom::Point c0 = cubic_bezier[0] * t;
Geom::Point c1 = cubic_bezier[1] * t;
Geom::Point c2 = cubic_bezier[2] * t;
Geom::Point c3 = cubic_bezier[3] * t;
cubic_bbox(c0[0], c0[1], c1[0], c1[1], c2[0], c2[1], c3[0], c3[1], bbox);
} else {
// should handle all not-so-easy curves:
Geom::Curve *ctemp = cit->transformed(t);
bbox.unionWith( ctemp->boundsExact());
delete ctemp;
}
}
}
//return Geom::bounds_exact(pv * t);
return bbox;
}
static void
geom_line_wind_distance (Geom::Coord x0, Geom::Coord y0, Geom::Coord x1, Geom::Coord y1, Geom::Point const &pt, int *wind, Geom::Coord *best)
{
Geom::Coord Ax, Ay, Bx, By, Dx, Dy, s;
Geom::Coord dist2;
/* Find distance */
Ax = x0;
Ay = y0;
Bx = x1;
By = y1;
Dx = x1 - x0;
Dy = y1 - y0;
const Geom::Coord Px = pt[X];
const Geom::Coord Py = pt[Y];
if (best) {
s = ((Px - Ax) * Dx + (Py - Ay) * Dy) / (Dx * Dx + Dy * Dy);
if (s <= 0.0) {
dist2 = (Px - Ax) * (Px - Ax) + (Py - Ay) * (Py - Ay);
} else if (s >= 1.0) {
dist2 = (Px - Bx) * (Px - Bx) + (Py - By) * (Py - By);
} else {
Geom::Coord Qx, Qy;
Qx = Ax + s * Dx;
Qy = Ay + s * Dy;
dist2 = (Px - Qx) * (Px - Qx) + (Py - Qy) * (Py - Qy);
}
if (dist2 < (*best * *best)) *best = sqrt (dist2);
}
if (wind) {
/* Find wind */
if ((Ax >= Px) && (Bx >= Px)) return;
if ((Ay >= Py) && (By >= Py)) return;
if ((Ay < Py) && (By < Py)) return;
if (Ay == By) return;
/* Ctach upper y bound */
if (Ay == Py) {
if (Ax < Px) *wind -= 1;
return;
} else if (By == Py) {
if (Bx < Px) *wind += 1;
return;
} else {
Geom::Coord Qx;
/* Have to calculate intersection */
Qx = Ax + Dx * (Py - Ay) / Dy;
if (Qx < Px) {
*wind += (Dy > 0.0) ? 1 : -1;
}
}
}
}
static void
geom_cubic_bbox_wind_distance (Geom::Coord x000, Geom::Coord y000,
Geom::Coord x001, Geom::Coord y001,
Geom::Coord x011, Geom::Coord y011,
Geom::Coord x111, Geom::Coord y111,
Geom::Point const &pt,
Geom::Rect *bbox, int *wind, Geom::Coord *best,
Geom::Coord tolerance)
{
Geom::Coord x0, y0, x1, y1, len2;
int needdist, needwind;
const Geom::Coord Px = pt[X];
const Geom::Coord Py = pt[Y];
needdist = 0;
needwind = 0;
if (bbox) cubic_bbox (x000, y000, x001, y001, x011, y011, x111, y111, *bbox);
x0 = std::min (x000, x001);
x0 = std::min (x0, x011);
x0 = std::min (x0, x111);
y0 = std::min (y000, y001);
y0 = std::min (y0, y011);
y0 = std::min (y0, y111);
x1 = std::max (x000, x001);
x1 = std::max (x1, x011);
x1 = std::max (x1, x111);
y1 = std::max (y000, y001);
y1 = std::max (y1, y011);
y1 = std::max (y1, y111);
if (best) {
/* Quickly adjust to endpoints */
len2 = (x000 - Px) * (x000 - Px) + (y000 - Py) * (y000 - Py);
if (len2 < (*best * *best)) *best = (Geom::Coord) sqrt (len2);
len2 = (x111 - Px) * (x111 - Px) + (y111 - Py) * (y111 - Py);
if (len2 < (*best * *best)) *best = (Geom::Coord) sqrt (len2);
if (((x0 - Px) < *best) && ((y0 - Py) < *best) && ((Px - x1) < *best) && ((Py - y1) < *best)) {
/* Point is inside sloppy bbox */
/* Now we have to decide, whether subdivide */
/* fixme: (Lauris) */
if (((y1 - y0) > 5.0) || ((x1 - x0) > 5.0)) {
needdist = 1;
}
}
}
if (!needdist && wind) {
if ((y1 >= Py) && (y0 < Py) && (x0 < Px)) {
/* Possible intersection at the left */
/* Now we have to decide, whether subdivide */
/* fixme: (Lauris) */
if (((y1 - y0) > 5.0) || ((x1 - x0) > 5.0)) {
needwind = 1;
}
}
}
if (needdist || needwind) {
Geom::Coord x00t, x0tt, xttt, x1tt, x11t, x01t;
Geom::Coord y00t, y0tt, yttt, y1tt, y11t, y01t;
Geom::Coord s, t;
t = 0.5;
s = 1 - t;
x00t = s * x000 + t * x001;
x01t = s * x001 + t * x011;
x11t = s * x011 + t * x111;
x0tt = s * x00t + t * x01t;
x1tt = s * x01t + t * x11t;
xttt = s * x0tt + t * x1tt;
y00t = s * y000 + t * y001;
y01t = s * y001 + t * y011;
y11t = s * y011 + t * y111;
y0tt = s * y00t + t * y01t;
y1tt = s * y01t + t * y11t;
yttt = s * y0tt + t * y1tt;
geom_cubic_bbox_wind_distance (x000, y000, x00t, y00t, x0tt, y0tt, xttt, yttt, pt, nullptr, wind, best, tolerance);
geom_cubic_bbox_wind_distance (xttt, yttt, x1tt, y1tt, x11t, y11t, x111, y111, pt, nullptr, wind, best, tolerance);
} else {
geom_line_wind_distance (x000, y000, x111, y111, pt, wind, best);
}
}
static void
geom_curve_bbox_wind_distance(Geom::Curve const & c, Geom::Affine const &m,
Geom::Point const &pt,
Geom::Rect *bbox, int *wind, Geom::Coord *dist,
Geom::Coord tolerance, Geom::Rect const *viewbox,
Geom::Point &p0) // pass p0 through as it represents the last endpoint added (the finalPoint of last curve)
{
unsigned order = 0;
if (Geom::BezierCurve const* b = dynamic_cast<Geom::BezierCurve const*>(&c)) {
order = b->order();
}
if (order == 1) {
Geom::Point pe = c.finalPoint() * m;
if (bbox) {
bbox->expandTo(pe);
}
if (dist || wind) {
if (wind) { // we need to pick fill, so do what we're told
geom_line_wind_distance (p0[X], p0[Y], pe[X], pe[Y], pt, wind, dist);
} else { // only stroke is being picked; skip this segment if it's totally outside the viewbox
Geom::Rect swept(p0, pe);
if (!viewbox || swept.intersects(*viewbox))
geom_line_wind_distance (p0[X], p0[Y], pe[X], pe[Y], pt, wind, dist);
}
}
p0 = pe;
}
else if (order == 3) {
Geom::CubicBezier const& cubic_bezier = static_cast<Geom::CubicBezier const&>(c);
Geom::Point p1 = cubic_bezier[1] * m;
Geom::Point p2 = cubic_bezier[2] * m;
Geom::Point p3 = cubic_bezier[3] * m;
// get approximate bbox from handles (convex hull property of beziers):
Geom::Rect swept(p0, p3);
swept.expandTo(p1);
swept.expandTo(p2);
if (!viewbox || swept.intersects(*viewbox)) { // we see this segment, so do full processing
geom_cubic_bbox_wind_distance ( p0[X], p0[Y],
p1[X], p1[Y],
p2[X], p2[Y],
p3[X], p3[Y],
pt,
bbox, wind, dist, tolerance);
} else {
if (wind) { // if we need fill, we can just pretend it's a straight line
geom_line_wind_distance (p0[X], p0[Y], p3[X], p3[Y], pt, wind, dist);
} else { // otherwise, skip it completely
}
}
p0 = p3;
} else {
//this case handles sbasis as well as all other curve types
Geom::Path sbasis_path = Geom::cubicbezierpath_from_sbasis(c.toSBasis(), 0.1);
//recurse to convert the new path resulting from the sbasis to svgd
for (const auto & iter : sbasis_path) {
geom_curve_bbox_wind_distance(iter, m, pt, bbox, wind, dist, tolerance, viewbox, p0);
}
}
}
/* Calculates...
and returns ... in *wind and the distance to ... in *dist.
Returns bounding box in *bbox if bbox!=NULL.
*/
void
pathv_matrix_point_bbox_wind_distance (Geom::PathVector const & pathv, Geom::Affine const &m, Geom::Point const &pt,
Geom::Rect *bbox, int *wind, Geom::Coord *dist,
Geom::Coord tolerance, Geom::Rect const *viewbox)
{
if (pathv.empty()) {
if (wind) *wind = 0;
if (dist) *dist = Geom::infinity();
return;
}
// remember last point of last curve
Geom::Point p0(0,0);
// remembering the start of subpath
Geom::Point p_start(0,0);
bool start_set = false;
for (const auto & it : pathv) {
if (start_set) { // this is a new subpath
if (wind && (p0 != p_start)) // for correct fill picking, each subpath must be closed
geom_line_wind_distance (p0[X], p0[Y], p_start[X], p_start[Y], pt, wind, dist);
}
p0 = it.initialPoint() * m;
p_start = p0;
start_set = true;
if (bbox) {
bbox->expandTo(p0);
}
// loop including closing segment if path is closed
for (Geom::Path::const_iterator cit = it.begin(); cit != it.end_default(); ++cit) {
geom_curve_bbox_wind_distance(*cit, m, pt, bbox, wind, dist, tolerance, viewbox, p0);
}
}
if (start_set) {
if (wind && (p0 != p_start)) // for correct picking, each subpath must be closed
geom_line_wind_distance (p0[X], p0[Y], p_start[X], p_start[Y], pt, wind, dist);
}
}
//#################################################################################
/*
* Converts all segments in all paths to Geom::LineSegment or Geom::HLineSegment or
* Geom::VLineSegment or Geom::CubicBezier.
*/
Geom::PathVector
pathv_to_linear_and_cubic_beziers( Geom::PathVector const &pathv )
{
Geom::PathVector output;
for (const auto & pit : pathv) {
output.push_back( Geom::Path() );
output.back().setStitching(true);
output.back().start( pit.initialPoint() );
for (Geom::Path::const_iterator cit = pit.begin(); cit != pit.end_open(); ++cit) {
if (is_straight_curve(*cit)) {
Geom::LineSegment l(cit->initialPoint(), cit->finalPoint());
output.back().append(l);
} else {
Geom::BezierCurve const *curve = dynamic_cast<Geom::BezierCurve const *>(&*cit);
if (curve && curve->order() == 3) {
Geom::CubicBezier b((*curve)[0], (*curve)[1], (*curve)[2], (*curve)[3]);
output.back().append(b);
} else {
// convert all other curve types to cubicbeziers
Geom::Path cubicbezier_path = Geom::cubicbezierpath_from_sbasis(cit->toSBasis(), 0.1);
cubicbezier_path.close(false);
output.back().append(cubicbezier_path);
}
}
}
output.back().close( pit.closed() );
}
return output;
}
/*
* Converts all segments in all paths to Geom::LineSegment. There is an intermediate
* stage where some may be converted to beziers. maxdisp is the maximum displacement from
* the line segment to the bezier curve; ** maxdisp is not used at this moment **.
*
* This is NOT a terribly fast method, but it should give a solution close to the one with the
* fewest points.
*/
Geom::PathVector
pathv_to_linear( Geom::PathVector const &pathv, double /*maxdisp*/)
{
Geom::PathVector output;
Geom::PathVector tmppath = pathv_to_linear_and_cubic_beziers(pathv);
// Now all path segments are either already lines, or they are beziers.
for (const auto & pit : tmppath) {
output.push_back( Geom::Path() );
output.back().start( pit.initialPoint() );
output.back().close( pit.closed() );
for (Geom::Path::const_iterator cit = pit.begin(); cit != pit.end_open(); ++cit) {
if (is_straight_curve(*cit)) {
Geom::LineSegment ls(cit->initialPoint(), cit->finalPoint());
output.back().append(ls);
}
else { /* all others must be Bezier curves */
Geom::BezierCurve const *curve = dynamic_cast<Geom::BezierCurve const *>(&*cit);
std::vector<Geom::Point> bzrpoints = curve->controlPoints();
Geom::Point A = bzrpoints[0];
Geom::Point B = bzrpoints[1];
Geom::Point C = bzrpoints[2];
Geom::Point D = bzrpoints[3];
std::vector<Geom::Point> pointlist;
pointlist.push_back(A);
recursive_bezier4(
A[X], A[Y],
B[X], B[Y],
C[X], C[Y],
D[X], D[Y],
pointlist,
0);
pointlist.push_back(D);
Geom::Point r1 = pointlist[0];
for (unsigned int i=1; i<pointlist.size();i++){
Geom::Point prev_r1 = r1;
r1 = pointlist[i];
Geom::LineSegment ls(prev_r1, r1);
output.back().append(ls);
}
pointlist.clear();
}
}
}
return output;
}
/*
* Converts all segments in all paths to Geom Cubic bezier.
* This is used in lattice2 LPE, maybe is better move the function to the effect
* But maybe could be usable by others, so i put here.
* The straight curve part is needed as is for the effect to work appropriately
*/
Geom::PathVector
pathv_to_cubicbezier( Geom::PathVector const &pathv)
{
Geom::PathVector output;
double cubicGap = 0.01;
for (const auto & pit : pathv) {
if (pit.empty()) {
continue;
}
output.push_back( Geom::Path() );
output.back().start( pit.initialPoint() );
output.back().close( pit.closed() );
bool end_open = false;
if (pit.closed()) {
const Geom::Curve &closingline = pit.back_closed();
if (!are_near(closingline.initialPoint(), closingline.finalPoint())) {
end_open = true;
}
}
Geom::Path pitCubic = (Geom::Path)pit;
if(end_open && pit.closed()){
pitCubic.close(false);
pitCubic.appendNew<Geom::LineSegment>( pitCubic.initialPoint() );
pitCubic.close(true);
}
for (Geom::Path::iterator cit = pitCubic.begin(); cit != pitCubic.end_open(); ++cit) {
if (is_straight_curve(*cit)) {
Geom::CubicBezier b(cit->initialPoint(), cit->pointAt(0.3334) + Geom::Point(cubicGap,cubicGap), cit->finalPoint(), cit->finalPoint());
output.back().append(b);
} else {
Geom::BezierCurve const *curve = dynamic_cast<Geom::BezierCurve const *>(&*cit);
if (curve && curve->order() == 3) {
Geom::CubicBezier b((*curve)[0], (*curve)[1], (*curve)[2], (*curve)[3]);
output.back().append(b);
} else {
// convert all other curve types to cubicbeziers
Geom::Path cubicbezier_path = Geom::cubicbezierpath_from_sbasis(cit->toSBasis(), 0.1);
output.back().append(cubicbezier_path);
}
}
}
}
return output;
}
//Study move to 2Geom
size_t
count_pathvector_nodes(Geom::PathVector const &pathv) {
size_t tot = 0;
for (auto subpath : pathv) {
tot += count_path_nodes(subpath);
}
return tot;
}
size_t count_path_nodes(Geom::Path const &path)
{
size_t tot = path.size_closed();
if (path.closed()) {
const Geom::Curve &closingline = path.back_closed();
// the closing line segment is always of type
// Geom::LineSegment.
if (are_near(closingline.initialPoint(), closingline.finalPoint())) {
// closingline.isDegenerate() did not work, because it only checks for
// *exact* zero length, which goes wrong for relative coordinates and
// rounding errors...
// the closing line segment has zero-length. So stop before that one!
tot -= 1;
}
}
return tot;
}
// The next routine is modified from curv4_div::recursive_bezier from file agg_curves.cpp
//----------------------------------------------------------------------------
// Anti-Grain Geometry (AGG) - Version 2.5
// A high quality rendering engine for C++
// Copyright (C) 2002-2006 Maxim Shemanarev
// Contact: mcseem@antigrain.com
// mcseemagg@yahoo.com
// http://antigrain.com
//
// AGG is free software; you can redistribute it and/or
// modify it under the terms of the GNU General Public License
// as published by the Free Software Foundation; either version 2
// of the License, or (at your option) any later version.
//
// AGG is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
//
// You should have received a copy of the GNU General Public License
// along with AGG; if not, write to the Free Software
// Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston,
// MA 02110-1301, USA.
//----------------------------------------------------------------------------
void
recursive_bezier4(const double x1, const double y1,
const double x2, const double y2,
const double x3, const double y3,
const double x4, const double y4,
std::vector<Geom::Point> &m_points,
int level)
{
// some of these should be parameters, but do it this way for now.
const double curve_collinearity_epsilon = 1e-30;
const double curve_angle_tolerance_epsilon = 0.01;
double m_cusp_limit = 0.0;
double m_angle_tolerance = 0.0;
double m_approximation_scale = 1.0;
double m_distance_tolerance_square = 0.5 / m_approximation_scale;
m_distance_tolerance_square *= m_distance_tolerance_square;
enum curve_recursion_limit_e { curve_recursion_limit = 32 };
#define calc_sq_distance(A,B,C,D) ((A-C)*(A-C) + (B-D)*(B-D))
if(level > curve_recursion_limit)
{
return;
}
// Calculate all the mid-points of the line segments
//----------------------
double x12 = (x1 + x2) / 2;
double y12 = (y1 + y2) / 2;
double x23 = (x2 + x3) / 2;
double y23 = (y2 + y3) / 2;
double x34 = (x3 + x4) / 2;
double y34 = (y3 + y4) / 2;
double x123 = (x12 + x23) / 2;
double y123 = (y12 + y23) / 2;
double x234 = (x23 + x34) / 2;
double y234 = (y23 + y34) / 2;
double x1234 = (x123 + x234) / 2;
double y1234 = (y123 + y234) / 2;
// Try to approximate the full cubic curve by a single straight line
//------------------
double dx = x4-x1;
double dy = y4-y1;
double d2 = fabs(((x2 - x4) * dy - (y2 - y4) * dx));
double d3 = fabs(((x3 - x4) * dy - (y3 - y4) * dx));
double da1, da2, k;
switch((int(d2 > curve_collinearity_epsilon) << 1) +
int(d3 > curve_collinearity_epsilon))
{
case 0:
// All collinear OR p1==p4
//----------------------
k = dx*dx + dy*dy;
if(k == 0)
{
d2 = calc_sq_distance(x1, y1, x2, y2);
d3 = calc_sq_distance(x4, y4, x3, y3);
}
else
{
k = 1 / k;
da1 = x2 - x1;
da2 = y2 - y1;
d2 = k * (da1*dx + da2*dy);
da1 = x3 - x1;
da2 = y3 - y1;
d3 = k * (da1*dx + da2*dy);
if(d2 > 0 && d2 < 1 && d3 > 0 && d3 < 1)
{
// Simple collinear case, 1---2---3---4
// We can leave just two endpoints
return;
}
if(d2 <= 0) d2 = calc_sq_distance(x2, y2, x1, y1);
else if(d2 >= 1) d2 = calc_sq_distance(x2, y2, x4, y4);
else d2 = calc_sq_distance(x2, y2, x1 + d2*dx, y1 + d2*dy);
if(d3 <= 0) d3 = calc_sq_distance(x3, y3, x1, y1);
else if(d3 >= 1) d3 = calc_sq_distance(x3, y3, x4, y4);
else d3 = calc_sq_distance(x3, y3, x1 + d3*dx, y1 + d3*dy);
}
if(d2 > d3)
{
if(d2 < m_distance_tolerance_square)
{
m_points.emplace_back(x2, y2);
return;
}
}
else
{
if(d3 < m_distance_tolerance_square)
{
m_points.emplace_back(x3, y3);
return;
}
}
break;
case 1:
// p1,p2,p4 are collinear, p3 is significant
//----------------------
if(d3 * d3 <= m_distance_tolerance_square * (dx*dx + dy*dy))
{
if(m_angle_tolerance < curve_angle_tolerance_epsilon)
{
m_points.emplace_back(x23, y23);
return;
}
// Angle Condition
//----------------------
da1 = fabs(atan2(y4 - y3, x4 - x3) - atan2(y3 - y2, x3 - x2));
if(da1 >= M_PI) da1 = 2*M_PI - da1;
if(da1 < m_angle_tolerance)
{
m_points.emplace_back(x2, y2);
m_points.emplace_back(x3, y3);
return;
}
if(m_cusp_limit != 0.0)
{
if(da1 > m_cusp_limit)
{
m_points.emplace_back(x3, y3);
return;
}
}
}
break;
case 2:
// p1,p3,p4 are collinear, p2 is significant
//----------------------
if(d2 * d2 <= m_distance_tolerance_square * (dx*dx + dy*dy))
{
if(m_angle_tolerance < curve_angle_tolerance_epsilon)
{
m_points.emplace_back(x23, y23);
return;
}
// Angle Condition
//----------------------
da1 = fabs(atan2(y3 - y2, x3 - x2) - atan2(y2 - y1, x2 - x1));
if(da1 >= M_PI) da1 = 2*M_PI - da1;
if(da1 < m_angle_tolerance)
{
m_points.emplace_back(x2, y2);
m_points.emplace_back(x3, y3);
return;
}
if(m_cusp_limit != 0.0)
{
if(da1 > m_cusp_limit)
{
m_points.emplace_back(x2, y2);
return;
}
}
}
break;
case 3:
// Regular case
//-----------------
if((d2 + d3)*(d2 + d3) <= m_distance_tolerance_square * (dx*dx + dy*dy))
{
// If the curvature doesn't exceed the distance_tolerance value
// we tend to finish subdivisions.
//----------------------
if(m_angle_tolerance < curve_angle_tolerance_epsilon)
{
m_points.emplace_back(x23, y23);
return;
}
// Angle & Cusp Condition
//----------------------
k = atan2(y3 - y2, x3 - x2);
da1 = fabs(k - atan2(y2 - y1, x2 - x1));
da2 = fabs(atan2(y4 - y3, x4 - x3) - k);
if(da1 >= M_PI) da1 = 2*M_PI - da1;
if(da2 >= M_PI) da2 = 2*M_PI - da2;
if(da1 + da2 < m_angle_tolerance)
{
// Finally we can stop the recursion
//----------------------
m_points.emplace_back(x23, y23);
return;
}
if(m_cusp_limit != 0.0)
{
if(da1 > m_cusp_limit)
{
m_points.emplace_back(x2, y2);
return;
}
if(da2 > m_cusp_limit)
{
m_points.emplace_back(x3, y3);
return;
}
}
}
break;
}
// Continue subdivision
//----------------------
recursive_bezier4(x1, y1, x12, y12, x123, y123, x1234, y1234, m_points, level + 1);
recursive_bezier4(x1234, y1234, x234, y234, x34, y34, x4, y4, m_points, level + 1);
}
void
swap(Geom::Point &A, Geom::Point &B){
Geom::Point tmp = A;
A = B;
B = tmp;
}
/*
Local Variables:
mode:c++
c-file-style:"stroustrup"
c-file-offsets:((innamespace . 0)(inline-open . 0)(case-label . +))
indent-tabs-mode:nil
fill-column:99
End:
*/
// vim: filetype=cpp:expandtab:shiftwidth=4:tabstop=8:softtabstop=4:fileencoding=utf-8:textwidth=99 :
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